| Photon Dynamics, Inc. Patent applications |
| Patent application number | Title | Published |
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| 20120038977 | HIGH SPEED ACQUISITION VISION SYSTEM AND METHOD FOR SELECTIVELY VIEWING OBJECT FEATURES - System and method for selectively viewing features of objects, including features hidden under non-transparent materials. The system includes: illuminating light source producing illuminating light having controlled angular spectrum; homogenizing optics for spatial intensity modulation of illumination light; dephasing optics to reduce or suppress interference pattern in image due to the coherence of illumination light; infinity corrected objective directing the illuminating light on the object and collecting light from the object; illumination optical path delivering the illuminating light from the illuminating light source to infinity-corrected objective; relay optics for introducing necessary tilt angle for rays of the illuminating light entering the infinity corrected objective; adjustable iris vignetting free aperture of optical fiber; apodizing element within relay optics for spatial modulation of illumination intensity; image sensor for creating image of object; and imaging optical path for delivering light from object to image sensor, which includes tube lens, removable block and adjustable iris. | 02-16-2012 |
| 20100045334 | DIRECT DETECT SENSOR FOR FLAT PANEL DISPLAYS - Each sensor of a linear array of sensors includes, in part, a sensing electrode and an associated feedback circuit. The sensing electrodes are adapted to be brought in proximity to a flat panel having formed thereon a multitude of pixel electrodes in order to capacitively measure the voltage of the pixel electrodes. Each feedback circuit is adapted to actively drive its associated electrode via a feedback signal so as to maintain the voltage of its associated electrode at a substantially fixed bias. Each feedback circuit may include an amplifier having a first input terminal coupled to the sensing electrode and a second input terminal coupled to receive a biasing voltage. The output signal of the amplification circuit is used to generate the feedback signal that actively drives the sensing electrode. The biasing voltage may be the ground potential. | 02-25-2010 |
| 20090295425 | DIRECT DETECT SENSOR FOR FLAT PANEL DISPLAYS - Each sensor of a linear array of sensors includes, in part, a sensing electrode and an associated feedback circuit. The sensing electrodes are adapted to be brought in proximity to a flat panel having formed thereon a multitude of pixel electrodes in order to capacitively measure the voltage of the pixel electrodes. Each feedback circuit is adapted to actively drive its associated electrode via a feedback signal so as to maintain the voltage of its associated electrode at a substantially fixed bias. Each feedback circuit may include an amplifier having a first input terminal coupled to the sensing electrode and a second input terminal coupled to receive a biasing voltage. The output signal of the amplification circuit is used to generate the feedback signal that actively drives the sensing electrode. The biasing voltage may be the ground potential. | 12-03-2009 |
| 20090074987 | LASER DECAL TRANSFER OF ELECTRONIC MATERIALS - A laser decal transfer is used to generate thin film features by directing laser pulses of very low energy at the back of a target substrate illuminating an area of a thin layer of a high viscosity rheological fluid coating the front surface of the target. The illuminated area is shaped and defined by an aperture centered about the laser beam. The decal transfer process allows for the release and transfer from the target substrate to the receiving substrate a uniform and continuous layer identical in shape and size of the laser irradiated area. The released layer is transferred across the gap with almost no changes to its initial size and shape. The resulting patterns transferred onto the receiving substrate are highly uniform in thickness and morphology, have sharp edge features and exhibit high adhesion, independent of the surface energy, wetting or phobicity of the receiving substrate. | 03-19-2009 |
| 20080315908 | DIRECT DETECT SENSOR FOR FLAT PANEL DISPLAYS - Each sensor of a linear array of sensors includes, in part, a sensing electrode and an associated feedback circuit. The sensing electrodes are adapted to be brought in proximity to a flat panel having formed thereon a multitude of pixel electrodes in order to capacitively measure the voltage of the pixel electrodes. Each feedback circuit is adapted to actively drive its associated electrode via a feedback signal so as to maintain the voltage of its associated electrode at a substantially fixed bias. Each feedback circuit may include an amplifier having a first input terminal coupled to the sensing electrode and a second input terminal coupled to receive a biasing voltage. The output signal of the amplification circuit is used to generate the feedback signal that actively drives the sensing electrode. The biasing voltage may be the ground potential. | 12-25-2008 |
| 20080239208 | Polymer Dispersed Liquid Crystal Formulations for Modulator Fabrication - Embodiments of polymer dispersed liquid crystals (PDLCs) in accordance with the present invention comprise TL-series liquid crystal materials and a polymer matrix comprising polyacrylate resins having hydroxyl groups. These hydroxyl groups allow crosslinking by using isocyanate, improving mechanical properties and heat resistance. Typical ratios of liquid crystal to polymer range between about 50/50 to 70/30 (wt/wt). The PDLC materials exhibit enhanced sensitivity to driving voltages and higher transmission˜voltage (T-V) curve slope. In testing thin film transistors (TFTs), these PDLC materials can be used to compensate for an increased air gap accommodating flatness variation in the TFT substrate, and to reduce electrostatic forces between modulator and panel. Embodiments of PDLC materials in accordance with the present invention form solid films upon evaporation of the solvent. Homogeneity of embodiments of solvent-based PDLC formulations in accordance with the present invention allow for the use of many different coating methods, such as spin, doctor blade, and slot-die coatings. | 10-02-2008 |
| 20080230525 | LASER ABLATION USING MULTIPLE WAVELENGTHS - In laser micromachining and laser defect repair of a first material, a first set of one or more laser wavelengths is selected in accordance with the first material's absorption characteristics and is combined and delivered concurrently with a second set of one or more laser wavelengths which is selected in accordance with the absorption characteristics of a second material generated by and remaining from the ablating interaction of the first material with the first set of laser wavelengths. The concurrent presence of the second set of one or more laser wavelengths removes the residual second material. | 09-25-2008 |
| 20080206489 | Scratch and Mar Resistant Pdlc Modulator - A PDLC modulator is fabricated using at least one of a selection of specially-formulated UV curable organic hard coatings as a protective layer on the exposed side of polyester (Mylar) film. The hard coatings of various related types show good adhesion on a polyester film substrate, superior hardness and toughness, and have a slippery top surface, which minimizes unnecessary wear. The coating as applied on the modulator surface significantly reduces scratch damage on modulators caused by unexpected particles on the panels under test. In addition, the slip surface will reduce stickiness to particles and therefore also reduce the possibility of panel damage. | 08-28-2008 |
| 20080198246 | SENSOR-BASED GAMMA CORRECTION OF A DIGITAL CAMERA - The anti-blooming structure of an image sensor is supplied with varying voltages during different integration periods such that charges generated in response to low level light are fully captured, whereas charges generated in response to a bright light spill over in a controlled manner. Accordingly, sensor's response may be generated to result in higher gains at low light levels and progressively lower gains at the higher light levels. | 08-21-2008 |
