Patent application number | Description | Published |
20110304240 | HIGH EFFICIENCY PIEZOELECTRIC MICRO-GENERATOR AND ENERGY STORAGE SYSTEM - This present invention provides a power supply for implanting into a patient's body and providing electricity to a load within the body, said power supply comprising an enclosure; adapted for optimizing an activating force by mechanisms of orienting thereof; the power supply further comprising (a) a piezoelectric micro-generator comprising (b) electrical energy storing means; (c) control unit adapted for managing charging and discharging said storing means said control unit further provided with means for decoupling said piezoelectric element from and connecting to said electrical energy storing means to increase efficiency of said power supply. | 12-15-2011 |
20130149602 | LITHIUM-ION SECONDARY ELECTROCHEMICAL CELL AND METHOD OF MAKING LITHIUM-ION SECONDARY ELECTROCHEMICAL CELL - Disclosed are lithium-ion secondary electrochemical cells and methods of making lithium-ion secondary electrochemical cells. | 06-13-2013 |
20130309549 | MEMBRANES SUITABLE FOR USE AS SEPARATORS AND ELECTROCHEMICAL CELLS INCLUDING SUCH SEPARATORS - Disclosed are membranes suitable for use as separators in electrochemical cells as well as electrochemical cells, where the membranes are configured to substantially reduce the passage of multivalent ions therethrough without substantially reducing the permeability of the membranes to lithium ions. | 11-21-2013 |
20130337304 | POUCH CELL COMPRISING AN EMPTY-VOLUME DEFINING COMPONENT - Disclosed are pouch cells, for example lithium-ion pouch cells, where a portion of the inner volume of the pouch is substantially empty and there is subatmospheric pressure inside the pouch. In some embodiments gas released inside the pouch, for example during use of the cell, is accommodated in the substantially empty portion of the inner volume of the pouch, avoiding pouch bulging. | 12-19-2013 |
Patent application number | Description | Published |
20090256921 | CAMERA EXPOSURE OPTIMIZATION TECHNIQUES THAT TAKE CAMERA AND SCENE MOTION INTO ACCOUNT - Quantities of motion regarding an imaging device such as an electronic camera are calculated and used to adjust the exposure time and one or more other exposure parameters used to capture an image to improve the quality of the image. Motion blur caused by movement of the camera or by movement of an object within the scene being photographed is reduced by selecting appropriate exposure parameters. Further, when there is little or no motion detected, the exposure parameters may be selected to improve the depth of field and reduce the noise in the captured image. | 10-15-2009 |
20100026868 | Wide Dynamic Range Image Capturing System Method and Apparatus - An image capture system is presented where the dynamic range of photo imaging devices, such as a still or video camera, is increased by varying sensor exposure time on a pixel-by-pixel basis under digital camera processor control. The systems photo sensors are continuously illuminated without reset over the exposure interval. In addition to being interrogated at the end of the exposure interval, the pixels are also non-destructively interrogated at one or more intermediate times during the interval. At each interrogation, the image capture system determines individually whether the pixels have saturated and if not, the parameter value is recorded; if the pixel has saturated, the previously stored value from the preceding interval is maintained. To produce the final sensor value for the whole exposure interval, the data for pixels that reached the saturation level are adjusted to compensate for their shortened exposure. | 02-04-2010 |
20100208101 | WIDE DYNAMIC RANGE IMAGE CAPTURING SYSTEM METHOD AND APPARATUS - An image capture system is presented where the dynamic range of photo imaging devices, such as a still or video camera, is increased by varying sensor exposure time on a pixel-by-pixel basis under digital camera processor control. The systems photo sensors are continuously illuminated without reset over the exposure interval. In addition to being interrogated at the end of the exposure interval, the pixels are also non-destructively interrogated at one or more intermediate times during the interval. At each interrogation, the image capture system determines individually whether the pixels have saturated and if not, the parameter value is recorded; if the pixel has saturated, the previously stored value from the preceding interval is maintained. To produce the final sensor value for the whole exposure interval, the data for pixels that reached the saturation level are adjusted to compensate for their shortened exposure. | 08-19-2010 |
20100328496 | ADVERTISING THROUGH RECYCLABLE DIGITAL CAMERAS - Data of updated or new advertising messages are loaded into a non-volatile memory of a digital camera in the course of it being recycled. The user of the camera therefore receives the updated or new advertising messages as a part of recycling the camera. There are a number of ways the advertising message can be displayed on a picture preview screen of the camera and/or reproduced by a loudspeaker on the camera. The advertising message can either be displayed along with a picture acquired by the camera or at separate times. | 12-30-2010 |