当社グループは 3,000 以上の世界的なカンファレンスシリーズ 米国、ヨーロッパ、世界中で毎年イベントが開催されます。 1,000 のより科学的な学会からの支援を受けたアジア および 700 以上の オープン アクセスを発行ジャーナルには 50,000 人以上の著名人が掲載されており、科学者が編集委員として名高い
。オープンアクセスジャーナルはより多くの読者と引用を獲得
700 ジャーナル と 15,000,000 人の読者 各ジャーナルは 25,000 人以上の読者を獲得
Noah Evans
Active matrix array innovation has made conceivable the idea of level board imaging frameworks for radiography. In the traditional methodology a flimsy film circuit based on glass contains the fundamental exchanging parts to readout a picture framed in either a phosphor or photoconductor layer. Expansion of this idea to constant imaging fluoroscopy has had issues because of the extremely low commotion required. Another plan methodology for fluoroscopic dynamic framework level board indicators has in this way been researched hypothetically. In this methodology, the dynamic network has coordinated dainty film enhancers and readout hardware at every pixel and is known as the intensified pixel locator cluster (APDA). Each intensified pixel comprises of three dainty film semiconductors: an intensifier, readout, and a reset TFT. The exhibition of the APDA approach contrasted with the ordinary dynamic lattice was researched for two semiconductors ordinarily used to develop dynamic framework clusters - hydrogenated formless silicon and polycrystalline silicon. The outcomes showed that with intensification near the pixel, the commotion from the outer charge preamplifiers becomes unimportant. The warm and gleam commotion of the readout and the intensifying TFTs at the pixel become the predominant wellsprings of clamor. The extent of these commotion sources is firmly reliant upon the TFT math and its creation cycle. Both of these could be enhanced to cause the APDA dynamic framework to work at lower commotion levels than is conceivable with the regular methodology. Notwithstanding, the APDA can't be made to work in a perfect world at the most minimal openness rate needed in clinical fluoroscopy.