Abstract: A communication system includes an optical “LAN” (50) interconnecting a plurality of information sources (16a) and sinks (22a) with a light-to-electrical converter (36a) associated with an electrical RF transmitters (32a) and an RF-to-light converter (38a) to a receiver (34a). The transmitter is coupled by way of electrical-to-light converter (46a), and the receiver is coupled by way of light-to-electrical converter (44a), and by way of a directional coupler (76a), to an end of an optical bus (74a), so that light signals representing signals to be transmitted flow in one direction, and light signals representing received signals flow in the other direction through the bus. A directional coupler (72a) at the other end of the optical bus routes the transmit light signals to a light-to-RF converter (47a) which feeds a sink or antenna (12a), and received signals from a source or antenna are routed by way of an RF-to-light converter (40a) and the directional coupler (72a) onto the optical bus (74a).

Abstract: A spatially-resolved spectrometer is used to measure streaking in molded sample plastic parts produced using a molding tool with various mold inserts which produce certain desired topological surface features upon these sample plastic parts. The measurements from one or more of these sample plastic parts are then provided to a computerized device which appropriately filters the data and calculates overall data shape, average peak and valley shift, and a quality number indicative of data slopes. These calculations are then used to determine an optimum set of ingredients and processing conditions to be used for the full-scale plastic part production.

Abstract: A communication system includes an optical “LAN” (50) interconnecting a plurality of information sources (16a) and sinks (22a) with a light-to-electrical converter (36a) associated with an electrical RF transmitters (32a) and an RF-to-light converter (38a) to a receiver (34a). The transmitter is coupled by way of electrical-to-light converter (46a), and the receiver is coupled by way of light-to-electrical converter (44a), and by way of a directional coupler (76a), to an end of an optical bus (74a), so that light signals representing signals to be transmitted flow in one direction, and light signals representing received signals flow in the other direction through the bus. A directional coupler (72a) at the other end of the optical bus routes the transmit light signals to a light-to-RF converter (47a) which feeds a sink or antenna (12a), and received signals from a source or antenna are routed by way of an RF-to-light converter (40a) and the directional coupler (72a) onto the optical bus (74a).

Abstract: Using the molding tool (2), spatially-resolved spectrometer (1) and computerized device (101) of U.S. patent application Ser. No. 09/303,409, streaking problems identified in production are first diagnosed (140), then duplicated on a laboratory scale (142) and compared with the streaking problems observed in production. Next, options are developed and tested for fixing (correcting) the observed problem and testing these on a laboratory scale (144). Finally, the option(s) chosen for correcting the observed problem are validated prior to reinitiating full-scale production (146).

Abstract: A patterned sample is analyzed by traversing a light spot across the sample and analyzing detected color at several sites to spatially resolve the pattern. A pattern analyzer includes a holder for supporting the sample which is illuminated by projecting the light spot onto the sample. A color sensor receives light reflected by the sample at the light spot and analyzes color of the sample at the spot. The spot is traversed across the sample surface to obtain a plurality of color readings across the surface to spatially resolve the pattern.

Abstract: An apparatus for sensing blend segregation in a mixture comprises a light transmissive window disposed within a feed connection between a hopper and an extruder for example, a light source for emitting a light beam, and a light sensor to perform spectrum analysis of any incident light supplied thereto. An illumination assembly has a first end optically coupled to the light source and a second end optically coupled to the light transmissive window to illuminate a portion of the internal path provided by the feed connection. At least one detection assembly is provided, having a first end disposed adjacent to the light transmissive window so as to detect the reflection from any illuminated polymer blend passing therethrough. The light sensor collects the diffuse reflecting light from the polymer blend and transforms the diffuse reflecting light into tri-color signals, reflection curves or the like, for comparison with other diffuse reflecting light so as to determine if a particular blend is segregating.

Abstract: A probe is configured for measuring color in a sample of material having a refractive index. The probe includes a light source that emits a light beam toward the sample. A color sensor is disposed at an oblique angle with the light source and directed toward a common probe zone for containing the sample. The light source and sensor are optically aligned with a reference plane in the probe zone to effect angles of incidence and reflection relative to the zone having a magnitude substantially equal to Brewster's maximum polarization angle for the refractive index of the sample, for measuring interior color of the sample.

Abstract: A sample having a coined line is analyzed by traversing a light spot across the sample, and then analyzing both specular and diffuse light reflected from the sample to spatially resolve the coined line. An analyzer includes a holder for supporting the sample which is illuminated by projecting the light spot onto the sample. Light collectors receive the specular and diffuse light from the sample at the spot. The received light is analyzed to detect changes therein indicative of the coined line.

Abstract: An apparatus for sensing color blend homogeneity in a mixture having a first and second blend portion includes a light transmissive plate for holding the mixture, a light source for emitting a light beam, and a color sensor optically coupled to the light source. An illumination assembly has a first end optically coupled to the light source and a second end optically coupled to and disposed normal to the light transmissive plate so as to illuminate the mixture disposed on the plate with the light beam. At least one detection assembly is provided, having a first end disposed adjacent the light transmissive plate so as to detect the diffuse reflection from the illuminated mixture. Next, the color sensor collects the diffuse reflecting light from the first and second material blends and transforms the diffuse reflecting light into tri-color signals so as to determine the local and global homogeneity of the first and second material blend portions.

Abstract: The instant invention is directed in general to optical systems in which a laser beam is injected into the end of an optical fiber and, more specifically, to laser materials processing systems in which a high power laser beam is injected into the fiber input end for transmission to a remote end of the fiber where materials processing is performed with the emitted beam. In a preferred embodiment of the instant invention, an injection chamber is used to isolate the optical fiber injection end from the surrounding air by enclosing the optical fiber injection end, and providing a gas purge to reduce the air concentration and to keep dust from entering or settling on the optical fiber injection end. This preferred embodiment prevents the ionization of the air surrounding the fiber injection end, thereby preventing the damaging effects of ionization which often occur during optical fiber injection processes.