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1、精选优质文档-倾情为你奉上Integrated CircuitsThe Integrated Circuit Digital logic and electronic circuits derive their functionality from electronic switches called transistor. Roughly speaking, the transistor can be likened to an electronically controlled valve whereby energy applied to one connection of the va
2、lve enables energy to flow between two other connections.By combining multiple transistors, digital logic building blocks such as AND gates and flip-flops are formed. Transistors, in turn, are made from semiconductors. Consult a periodic table of elements in a college chemistry textbook, and you wil
3、l locate semiconductors as a group of elements separating the metals and nonmetals.They are called semiconductors because of their ability to behave as both metals and nonmetals. A semiconductor can be made to conduct electricity like a metal or to insulate as a nonmetal does. These differing electr
4、ical properties can be accurately controlled by mixing the semiconductor with small amounts of other elements. This mixing is called doping. A semiconductor can be doped to contain more electrons (N-type) or fewer electrons (P-type). Examples of commonly used semiconductors are silicon and germanium
5、. Phosphorous and boron are two elements that are used to dope N-type and P-type silicon, respectively. A transistor is constructed by creating a sandwich of differently doped semiconductor layers. The two most common types of transistors, the bipolar-junction transistor (BJT) and the field-effect t
6、ransistor (FET) are schematically illustrated in Figure 2.1.This figure shows both the silicon structures of these elements and their graphical symbolic representation as would be seen in a circuit diagram. The BJT shown is an NPN transistor, because it is composed of a sandwich of N-P-N doped silic
7、on. When a small current is injected into the base terminal, a larger current is enabled to flow from the collector to the emitter.The FET shown is an N-channel FET, which is composed of two N-type regions separated by a P-type substrate. When a voltage is applied to the insulated gate terminal, a c
8、urrent is enabled to flow from the drain to the source. It is called N-channel, because the gate voltage induces an N-channel within the substrate, enabling current to flow between the N-regions. Another basic semiconductor structure is a diode, which is formed simply by a junction of N-type and P-t
9、ype silicon. Diodes act like one-way valves by conducting current only from P to N. Special diodes can be created that emit light when a voltage is applied. Appropriately enough, these components are called light emitting diodes, or LEDs. These small lights are manufactured by the millions and are f
10、ound in diverse applications from telephones to traffic lights. The resulting small chip of semiconductor material on which a transistor or diode is fabricated can be encased in a small plastic package for protection against damage and contamination from the outside world.Small wires are connected w
11、ithin this package between the semiconductor sandwich and pins that protrude from the package to make electrical contact with other parts of the intended circuit. Once you have several discrete transistors, digital logic can be built by directly wiring these components together. The circuit will fun
12、ction, but any substantial amount of digital logic will be very bulky, because several transistors are required to implement each of the various types of logic gates. At the time of the invention of the transistor in 1947 by John Bardeen, Walter Brattain, and William Shockley, the only way to assemb
13、le multiple transistors into a single circuit was to buy separate discrete transistors and wire them together. In 1959, Jack Kilby and Robert Noyce independently invented a means of fabricating multiple transistors on a single slab of semiconductor material. Their invention would come to be known as
14、 the integrated circuit, or IC, which is the foundation of our modern computerized world. An IC is so called because it integrates multiple transistors and diodes onto the same small semiconductor chip. Instead of having to solder individual wires between discrete components, an IC contains many sma
15、ll components that are already wired together in the desired topology to form a circuit. A typical IC, without its plastic or ceramic package, is a square or rectangular silicon die measuring from 2 to 15 mm on an edge. Depending on the level of technology used to manufacture the IC, there may be an
16、ywhere from a dozen to tens of millions of individual transistors on this small chip. This amazing density of electronic components indicates that the transistors and the wires that connect them are extremely small in size. Dimensions on an IC are measured in units of micrometers, with one micromete
17、r (1mm) being one millionth of a meter. To serve as a reference point, a human hair is roughly 100mm in diameter. Some modern ICs contain components and wires that are measured in increments as small as 0.1mm! Each year, researchers and engineers have been finding new ways to steadily reduce these f
18、eature sizes to pack more transistors into the same silicon area, as indicated in Figure 2.2. When an IC is designed and fabricated, it generally follows one of two main transistor technologies: bipolar or metal-oxide semiconductor (MOS). Bipolar processes create BJTs, whereas MOS processes create F
19、ETs. Bipolar logic was more common before the 1980s, but MOS technologies have since accounted the great majority of digital logic ICs. N-channel FETs are fabricated in an NMOS process, and P-channel FETs are fabricated in a PMOS process. In the 1980s, complementary-MOS, or CMOS, became the dominant
20、 process technology and remains so to this day. CMOS ICs incorporate both NMOS and PMOS transistors. 集成电路集成电路数字逻辑和电子电路由称为晶体管的电子开关得到它们的(各种)功能。粗略地说,晶体管好似一种电子控制阀,由此加在阀一端的能量可以使能量在另外两个连接端之间流动。通过多个晶体管的组合就可以构成数字逻辑模块,如与门和触发电路等。而晶体管是由半导体构成的。查阅大学化学书中的元素周期表,你会查到半导体是介于金属与非金属之间的一类元素。它们之所以被叫做半导体是由于它们表现出来的性质类似于金属和
21、非金属。可使半导体像金属那样导电,或者像非金属那样绝缘。通过半导体和少量其它元素的混合可以精确地控制这些不同的电特性,这种混合技术称之为“半导体掺杂”。半导体通过掺杂可以包含更多的电子(N型)或更少的电子(P型)。常用的半导体是硅和锗,N型硅半导体掺入磷元素,而P型硅半导体掺入硼元素。不同掺杂的半导体层形成的三明治状夹层结构可以构成一个晶体管,最常见的两类晶体管是双极型晶体管(BJT)和场效应晶体管(FET),图2.1给出了它们的图示。图中给出了这些晶体管的硅结构,以及它们用于电路图中的符号。BJT是NPN晶体管,因为由NPN掺杂硅三层构成。当小电流注入基极时,可使较大的电流从集电极流向发射极
22、。图示的FET是N沟道的场效应型晶体管,它由两块被P型基底分离的N型组成。将电压加在绝缘的栅极上时,可使电流由漏极流向源极。它被叫做N沟道是因为栅极电压诱导基底上的N通道,使电流能在两个N区域之间流动。另一个基本的半导体结构是二极管,由N型和P型硅连接而成的结组成。二极管的作用就像一个单向阀门,由于电流只能从P流向N。可以构建一些特殊二极管,在加电压时可以发光,这些器件非常合适地被叫做发光二极管或LED。这种小灯泡数以百万计地被制造出来,有各种各样的应用,从电话机到交通灯。半导体材料上制作晶体管或二极管所形成的小芯片用塑料封装以防损伤和被外界污染。在这封装里一些短线连接半导体夹层和从封装内伸出
23、的插脚以便与(使用该晶体管的)电路其余部分连接。一旦你有了一些分立的晶体管,直接用电线将这些器件连线在一起就可以构建数字逻辑(电路)。电路会工作,但任何实质性的数字逻辑(电路)都将十分庞大,因为要在各种逻辑门中每实现一种都需要多个晶体管。1947年,John Bardeen、Walter Brattain和and William Shockley发明晶体管的时候。将多个晶体管组装在一个电路上的唯一方法就是购买多个分离的晶体管,将它们连在一起。1959年,Jack Kilby 和 Robert Noyce各自独立地发明了一种将多个晶体管做在同一片半导体材料上的方法。这个发明就是集成电路,或IC,
24、是我们现代电脑化世界的基础。集成电路之所以被这样命名,是因为它将多个晶体管和二极管集成到同一块小的半导体芯片上。IC包含按照形成电路所要求的拓扑结构连在一起的许多小元件,而无需再将分立元件的导线焊接起来。去除了塑料或陶瓷封装后,一个典型的集成电路就是每一边2mm至15mm的方形或矩形硅片。根据制造集成电路的技术水平的不同,在这种小片上可能有几十个到几百万个晶体管,电子器件这种令人惊异的密度表明那些晶体管以及连接它们线是极其微小的。集成电路的尺寸是以微米为单位测量的,1微米是1米的百万分之一。作为参照,一根人的头发其直径大约为100微米。一些现代集成电路包含的元件和连线,是以小到0.1微米的增量
25、来测量的。每年研究人员和工程师都在寻找新的方法来不断减小这些元件的大小,以便在同样面积的硅片上集成更多的晶体管,如图2.2所示。在集成电路的设计和制造过程中,常用两种主要晶体管技术是:双极和金属氧化物半导体(MOS)。双极工艺生产出来的是BJT(双极型晶体管),而MOS工艺生产出来的是FET(场效应晶体管)。在20世纪80年代以前更常用的集成电路是双极逻辑,但是此后MOS技术在数字逻辑集成电路中占据了大多数。N沟道FET是采用NMOS工艺生产的,而P沟道FET是采用PMOS工艺生产的。到了20世纪80年代,互补MOS即CMOS成为占主导地位的加工技术,并且延续至今。CMOS集成电路包含了NMOS和PMOS两种晶体管。专心-专注-专业