{"id":478227,"date":"2023-08-09T09:29:27","date_gmt":"2023-08-09T09:29:27","guid":{"rendered":""},"modified":"2023-09-05T11:16:19","modified_gmt":"2023-09-05T11:16:19","slug":"not-logic-gate","status":"publish","type":"wiki","link":"https:\/\/oneproxy.pro\/tr\/wiki\/not-logic-gate\/","title":{"rendered":"Mant\u0131k kap\u0131s\u0131 DE\u011e\u0130L"},"content":{"rendered":"

\u0130nverter olarak da bilinen NOT mant\u0131k kap\u0131s\u0131, tek bir ikili giri\u015f \u00fczerinde \u00e7al\u0131\u015fan ve ters bir \u00e7\u0131k\u0131\u015f \u00fcreten temel bir dijital mant\u0131k kap\u0131s\u0131d\u0131r. Dijital devrelerde kullan\u0131lan en basit mant\u0131k kap\u0131lar\u0131ndan biridir ve modern bilgisayar ve elektronikte \u00e7ok \u00f6nemli bir rol oynar. NOT kap\u0131s\u0131 bir giri\u015f sinyali al\u0131r ve onu olumsuzlar; yani giri\u015f y\u00fcksekse (1), \u00e7\u0131k\u0131\u015f d\u00fc\u015f\u00fck (0) olacakt\u0131r ve bunun tersi de ge\u00e7erlidir.<\/p>\n

DE\u011e\u0130L mant\u0131k kap\u0131s\u0131n\u0131n k\u00f6keninin tarihi ve ilk s\u00f6z\u00fc<\/h2>\n

Mant\u0131k kap\u0131lar\u0131 kavram\u0131n\u0131n tarihi, George Boole'un modern dijital mant\u0131\u011f\u0131n temelini olu\u015fturan Boole cebrini tan\u0131tt\u0131\u011f\u0131 19. y\u00fczy\u0131l\u0131n ortalar\u0131na kadar uzanmaktad\u0131r. Ancak bug\u00fcn bildi\u011fimiz \u00f6zel DE\u011e\u0130L mant\u0131k kap\u0131s\u0131, 20. y\u00fczy\u0131l\u0131n ortalar\u0131nda elektronik bilgisayarlar\u0131n erken geli\u015fimi s\u0131ras\u0131nda ortaya \u00e7\u0131kt\u0131.<\/p>\n

NOT ge\u00e7idinin ilk s\u00f6z\u00fc, genellikle dijital devre tasar\u0131m\u0131n\u0131n babas\u0131 olarak kabul edilen Claude Shannon'un \u00e7al\u0131\u015fmalar\u0131na kadar uzanabilir. Shannon, 1937'de \u00e7\u0131\u011f\u0131r a\u00e7an y\u00fcksek lisans tezi "R\u00f6le ve Anahtarlama Devrelerinin Sembolik Analizi"nde, karma\u015f\u0131k Boolean ifadelerinin, NOT ge\u00e7idi de dahil olmak \u00fczere daha basit mant\u0131k kap\u0131lar\u0131 kullan\u0131larak nas\u0131l uygulanabilece\u011fini g\u00f6sterdi. \u00c7al\u0131\u015fmalar\u0131 elektronik hesaplama makinelerinde mant\u0131k kap\u0131lar\u0131n\u0131n kullan\u0131lmas\u0131n\u0131n temelini att\u0131.<\/p>\n

NOT mant\u0131k kap\u0131s\u0131 hakk\u0131nda detayl\u0131 bilgi. Mant\u0131k kap\u0131s\u0131 DE\u011e\u0130L konuyu geni\u015fletmek.<\/h2>\n

NOT kap\u0131s\u0131, dijital devrelerin temel yap\u0131 ta\u015f\u0131d\u0131r ve transist\u00f6rler, diyotlar veya r\u00f6leler gibi \u00e7e\u015fitli teknolojiler kullan\u0131larak in\u015fa edilmi\u015ftir. Basitli\u011fi ve \u00e7ok y\u00f6nl\u00fcl\u00fc\u011f\u00fc onu entegre devrelerde, mikroi\u015flemcilerde ve di\u011fer dijital sistemlerde \u00e7ok \u00f6nemli bir bile\u015fen haline getiriyor.<\/p>\n

NOT mant\u0131k kap\u0131s\u0131n\u0131n i\u00e7 yap\u0131s\u0131. NOT mant\u0131k kap\u0131s\u0131 nas\u0131l \u00e7al\u0131\u015f\u0131r?<\/h2>\n

NOT mant\u0131k kap\u0131s\u0131n\u0131n i\u00e7 yap\u0131s\u0131, uygulama i\u00e7in kullan\u0131lan teknolojiye ba\u011fl\u0131 olarak de\u011fi\u015febilir. Ancak temel prensip ayn\u0131 kal\u0131yor. Bir NOT ge\u00e7idi \u00f6z\u00fcnde tek bir giri\u015f (A) ve tek bir \u00e7\u0131k\u0131\u015ftan (Y) olu\u015fur.<\/p>\n

Transist\u00f6rlerin kullan\u0131ld\u0131\u011f\u0131 en basit uygulamada NOT ge\u00e7idi, toplay\u0131c\u0131s\u0131 g\u00fc\u00e7 kayna\u011f\u0131 voltaj\u0131na (Vcc) ve vericisi topra\u011fa (GND) ba\u011fl\u0131 olan tek bir transist\u00f6rden olu\u015fur. Giri\u015f sinyali (A) transist\u00f6r\u00fcn taban\u0131na ba\u011flan\u0131r. Giri\u015f lojik y\u00fcksek (1) oldu\u011funda, ak\u0131m transist\u00f6rden akar, onu doyurur ve \u00e7\u0131k\u0131\u015f lojik d\u00fc\u015f\u00fck (0) de\u011ferine \u00e7ekilir. Tersine, giri\u015f lojik d\u00fc\u015f\u00fck (0) oldu\u011funda, transist\u00f6r kapan\u0131r ve \u00e7\u0131k\u0131\u015f lojik y\u00fcksek (1) de\u011ferine \u00e7ekilir.<\/p>\n

NOT kap\u0131s\u0131n\u0131n \u00e7al\u0131\u015fmas\u0131 a\u015fa\u011f\u0131daki do\u011fruluk tablosuyla temsil edilebilir:<\/p>\n\n\n\n\n\n\n
Giri\u015f (A)<\/th>\n\u00c7\u0131k\u0131\u015f (Y)<\/th>\n<\/tr>\n<\/thead>\n
0<\/td>\n1<\/td>\n<\/tr>\n
1<\/td>\n0<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

NOT mant\u0131k kap\u0131s\u0131n\u0131n temel \u00f6zelliklerinin analizi<\/h2>\n

NOT mant\u0131k kap\u0131s\u0131, onu dijital devre tasar\u0131m\u0131nda hayati bir bile\u015fen haline getiren birka\u00e7 temel \u00f6zellik sergiler:<\/p>\n

    \n
  1. \n

    Tamamlay\u0131c\u0131 \u0130\u015flev:<\/strong> NOT kap\u0131s\u0131, giri\u015f de\u011ferini tersine \u00e7evirerek mant\u0131ksal bir tamamlama i\u015flemi ger\u00e7ekle\u015ftirir.<\/p>\n<\/li>\n

  2. \n

    Amplifikasyon:<\/strong> Transist\u00f6r tabanl\u0131 uygulamalarda NOT ge\u00e7idi, daha g\u00fc\u00e7l\u00fc \u00e7\u0131k\u0131\u015f sinyalleri \u00fcretmek i\u00e7in zay\u0131f giri\u015f sinyallerini de y\u00fckseltebilir.<\/p>\n<\/li>\n

  3. \n

    Sinyal Tersine \u00c7evirme:<\/strong> \u00c7e\u015fitli dijital devre uygulamalar\u0131nda gerekli olan bir sinyalin mant\u0131k seviyesini tersine \u00e7evirmek i\u00e7in s\u0131kl\u0131kla kullan\u0131l\u0131r.<\/p>\n<\/li>\n

  4. \n

    Mant\u0131k Seviyesi De\u011fi\u015ftirme:<\/strong> NOT ge\u00e7idi, sinyalleri bir mant\u0131k ailesinden di\u011ferine d\u00f6n\u00fc\u015ft\u00fcrebilir ve farkl\u0131 devre bile\u015fenleri aras\u0131ndaki uyumlulu\u011fu kolayla\u015ft\u0131r\u0131r.<\/p>\n<\/li>\n<\/ol>\n

    DE\u011e\u0130L mant\u0131k kap\u0131s\u0131n\u0131n t\u00fcrleri<\/h2>\n

    A\u015fa\u011f\u0131daki sembolle temsil edilen yaln\u0131zca bir standart DE\u011e\u0130L kap\u0131s\u0131 t\u00fcr\u00fc vard\u0131r:<\/p>\n

    Lua<\/span>