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UNIT- III Transistor Characteristics • BJT: Junction transistor, transistor current components, transistor equation, transistor configurations, transistor as an amplifier, characteristics of transistor in Common Base, Common Emitter and Common Collector configurations, EbersMoll model of a transistor, punch through/ reach through, Photo transistor, typical transistor junction voltage values. • FET: FETtypes, construction, operation, characteristics, parameters, MOSFET-types, construction, operation, characteristics, comparison between JFET and MOSFET. ECE 663 Transistor/switch/amplifier – a 3 terminal device Source Gate Incoherent Light Coherent Light Vein Artery Valve Gain medium Drain Laser Dam Emitter Collector Heart Ion Channel Base BJT MOSFET Axonal conduction ECE 663 All of these share a feature with… • Output current can toggle between large and small (Switching Digital logic; create 0s and 1s) • Small change in ‘valve’ (3rd terminal) creates Large change in output between 1st and 2nd terminal (Amplification Analog applications; Turn 0.5 50) Recall p-n junction W + P N N P W + - - Vappl < 0 Vappl > 0 Forward bias, + on P, - on N (Shrink W, Vbi) Reverse bias, + on N, - on P (Expand W, Vbi) Allow holes to jump over barrier into N region as minority carriers Remove holes and electrons away from depletion region I I V V So if we combine these by fusing their terminals… N P W + - Vappl > 0 P N W + - Vappl < 0 Holes from P region (“Emitter”) of 1st PN junction driven by FB of 1st PN junction into central N region (“Base”) Driven by RB of 2nd PN junction from Base into P region of 2nd junction (“Collector”) • 1st region FB, 2nd RB • If we want to worry about holes alone, need P+ on 1st region • For holes to be removed by collector, base region must be thin Bipolar Junction Transistors: Basics + - IE IC - + IB IE = I B + IC ………(KCL) VEC = VEB + VBC ……… (KVL) The BJT – Bipolar Junction Transistor Note: Normally Emitter layer is heavily doped, Base layer is lightly doped and Collector layer has Moderate doping. The Two Types of BJT Transistors: npn E n pnp p n C C Cross Section B E p n p C C Cross Section B B B Schematic Symbol Schematic Symbol E • Collector doping is usually ~ 109 • Base doping is slightly higher ~ 1010 – 1011 • Emitter doping is much higher ~ 1017 E BJT Current & Voltage - Equations IE E - VCE + IC IE C - - E + VEC IC - C + VBE IB VBC + VEB - + + B B VCB IB npn pnp IE = IB + IC VCE = -VBC + VBE IE = IB + IC VEC = VEB - VCB n I co VCB - Inc + - p- Electrons + Holes + VBE - Ipe Ine n+ Bulk-recombination Current Figure : Current flow (components) for an n-p-n BJT in the active region. NOTE: Most of the current is due to electrons moving from the emitter through base to the collector. Base current consists of holes crossing from the base into the emitter and of holes that recombine with electrons in the base. Physical Structure • Consists of 3 alternate layers of nand p-type semiconductor called emitter (E), base (B) and collector (C). • Majority of current enters collector, crosses base region and exits through emitter. A small current also enters base terminal, crosses baseemitter junction and exits through emitter. • Carrier transport in the active base region directly beneath the heavily doped (n+) emitter dominates i-v characteristics of BJT. Ic C Recombination VCB + - - - - -n - - - - - - - - - - _ - + - B - - - -+ - - p + + _ IB VBE - - - - - - --- - - - - - - - - - - - n - - - - - - - - - E - Electrons + Holes IE Bulk-recombination current ICO Inc For CB Transistor IE= Ine+ Ipe Ic= Inc- Ico And Ic= - αIE + ICo CB Current Gain, α ═ (Ic- Ico) . (IE- 0) For CE Trans., IC = βIb + (1+β) Ico where β ═ α , 1- α is CE Gain Ipe Ine Figure: An npn transistor with variable biasing sources (common-emitter configuration). Common-Emitter Circuit Diagram IC VC + _ Collector-Current Curves VCE IC IB C Active Region IB Region of Description Operation Active Small base current controls a large collector current Saturation VCE(sat) ~ 0.2V, VCE increases with IC Cutoff Achieved by reducing IB to 0, Ideally, IC will also be equal to 0. VCE Saturation Region Cutoff Region IB = 0 BJT’s have three regions of operation: 1) Active - BJT acts like an amplifier (most common use) 2) Saturation - BJT acts like a short circuit BJT is used as a switch by switching 3) Cutoff - BJT acts like an open circuit between these two regions. IC(mA) Saturation Region IB = 200 mA 30 When analyzing a DC BJT circuit, the BJT is replaced by one of the DC circuit models shown below. C Active Region IB = 150 mA 22.5 B E IB = 100 mA 15 IB = 50 mA 7.5 Cutoff Region IB = 0 0 VCE (V) 0 5 10 15 20 DC Models for a BJT: C C C rsat IB B B + _ B + _ b dc IB ICEO b dc IB Vo + _ RBB Vo Vo E E Saturat ion Region Model Active Region Model #1 E Active Region Model #2 Ro DC b and DC b = Common-emitter current gain = Common-base current gain b = IC = IC IB IE The relationships between the two parameters are: = b b= b+1 1- Note: and b are sometimes referred to as dc and bdc because the relationships being dealt with in the BJT are DC. Output characteristics: npn BJT (typical) IC(mA) b dc = IB = 200 mA 30 Note: The PE review text sometimes uses dc instead of bdc. They are related as follows: IB = 150 mA 22.5 IB = 100 mA 15 IB = 50 mA 7.5 IB = 0 0 0 5 10 15 20 Input characteristics: npn BJT (typical) IC = h FE IB dc = b dc b dc + 1 b dc dc 1 - dc VCE (V) • Find the approximate values of bdc and dc from the graph. IB(mA) VCE = 0.5 V 200 VCE = 0 VCE > 1 V 150 The input characteristics look like the characteristics of a forward-biased diode. Note that VBE varies only slightly, so we often ignore these characteristics and assume: Common approximation: VBE = Vo = 0.65 to 0.7V 100 Note: Two key specifications for the BJT are Bdc 50 and Vo (or assume Vo is about 0.7 V) 0 VBE (V) 0 0.5 1.0 Figure: Common-emitter characteristics displaying exaggerated secondary effects. Figure: Common-emitter characteristics displaying exaggerated secondary effects. Various Regions (Modes) of Operation of BJT Active: • Most important mode of operation • Central to amplifier operation • The region where current curves are practically flat Saturation: • Barrier potential of the junctions cancel each other out causing a virtual short (behaves as on state Switch) Cutoff: • Current reduced to zero • Ideal transistor behaves like an open switch * Note: There is also a mode of operation called inverse active mode, but it is rarely used. BJT Trans-conductance Curve For Typical NPN Transistor 1 Collector Current: IC = IES eVBE/VT Transconductance: (slope of the curve) IC 8 mA gm = IC / VBE IES = The reverse saturation current of the B-E Junction. VT = kT/q = 26 mV (@ T=300oK) = the emission coefficient and is usually ~1 6 mA 4 mA 2 mA 0.7 V VBE Three Possible Configurations of BJT Biasing the transistor refers to applying voltages to the transistor to achieve certain operating conditions. 1. Common-Base Configuration (CB) : input = VEB & IE output = VCB & IC 2. Common-Emitter Configuration (CE): input = VBE & IB output= VCE & IC 3. Common-Collector Configuration (CC) :input = VBC & IB (Also known as Emitter follower) output = VEC & IE Common-Base BJT Configuration Circuit Diagram: NPN Transistor C VCE IC VCB The Table Below lists assumptions that can be made for the attributes of the common-base BJT circuit in the different regions of operation. Given for a Silicon NPN transistor. Region of Operation IC Active bIB Saturation Max Cutoff ~0 VCE E VBE + _ + _ IB B VCB VBE =VBE+VCE ~0.7V ~0V IE VBE VCB 0V C-B Bias E-B Bias Rev. Fwd. ~0.7V -0.7V<VCE<0 Fwd. Fwd. =VBE+VCE 0V 0V Rev. None /Rev. Common-Base (CB) Characteristics Although the Common-Base configuration is not the most common configuration, it is often helpful in the understanding operation of BJT Vc- Ic (output) Characteristic Curves IC mA Breakdown Reg. Saturation Region 6 0.8V Active Region IE 4 IE=2mA 2 IE=1mA 2V 4V 6V 8V Cutoff IE = 0 VCB Common-Collector BJT Characteristics Emitter-Current Curves The Common-Collector biasing circuit is basically equivalent to the common-emitter biased circuit except instead of looking at IC as a function of VCE and IB we are looking at IE. Also, since ~ 1, and = IC/IE that means IC~IE IE Active Region IB VCE Saturation Region Cutoff Region IB = 0 n p n Transistor: Forward Active Mode Currents Base current is given by IC= I F 20 b IB= V I co BE 1 I C exp V B b b T F F 500 is forward common-emitter current gain Emitter current is given by VBE IE= Forward Collector current is V I co BE 1 I I I exp V E B C T F b is forward common- V F 1.0 0 . 95 BE base current gain 1 I I co exp F b 1 C V F T current Ico is reverse saturation In this forward active operation region, I I 18 9 C C 10 A Ico 10 A b F F I I B E VT = kT/q =25 mV at room temperature BJT configurations GAIN CONFIG ECE 663 Bipolar Junction Transistors: Basics + - IE IC - + IB VEB >-VBC > 0 VEC > 0 but small IE > -IC > 0 IB > 0 VEB, VBC > 0 VEC >> 0 IE, IC > 0 IB > 0 VEB < 0, VBC > 0 VEC > 0 IE < 0, IC > 0 IB > 0 but small ECE 663 Bipolar Junction Transistors: Basics Bias Mode E-B Junction C-B Junction Saturation Forward Forward Active Forward Reverse Inverted Reverse Forward Cutoff Reverse Reverse ECE 663 BJT Fabrication ECE 663 PNP BJT Electrostatics ECE 663 PNP BJT Electrostatics ECE 663 NPN Transistor Band Diagram: Equilibrium ECE 663 PNP Transistor Active Bias Mode VEB > 0 VCB > 0 Few recombine in the base Collector Fields drive holes far away where they can’t return thermionically Large injection of Holes Most holes diffuse to collector ECE 663 Forward Active minority carrier distribution P+ N P pB(x) nE(x’) nC0 nE0 pB0 nC(x’’) ECE 663 PNP Physical Currents ECE 663 PNP transistor amplifier action IN (small) OUT (large) Clearly this works in common emitter configuration ECE 663 Emitter Injection Efficiency - PNP IE E ICp IEp IEn ICn IC C IB IEp IEp IE IEp IEn Can we make the emitter see holes alone? 0 1 ECE 663 Base Transport Factor IE E ICp IEp IEn ICn IC C IB ICp T I Ep 0 T 1 Can all injected holes make it to the collector? ECE 663 Common Base DC current gain - PNP Common Base – Active Bias mode: IC = DCIE + ICB0 ICp = TIEp = TIE DC = T IC = TIE + ICn ECE 663 Common Emitter DC current gain - PNP Common Emitter – Active Bias mode: IE = bDCIB + ICE0 bDC = DC /(1-DC) IC = DCIE + ICB0 = DC(IC + IB) + ICB0 IC = DCIB + ICB0 1-DC GAIN !! IC IB IE ECE 663 Common Emitter DC current gain - PNP b dc T 1 T Thin base will make T 1 Highly doped P region will make 1 ECE 663 PNP BJT Common Emitter Characteristic ECE 663 Eber-Moll BJT Model The Eber-Moll Model for BJTs is fairly complex, but it is valid in all regions of BJT operation. The circuit diagram below shows all the components of the Eber-Moll Model: E IE IC RIC RIE IF IR IB B C Eber-Moll BJT Model R = Common-base current gain (in forward active mode) F = Common-base current gain (in inverse active mode) IES = Reverse-Saturation Current of B-E Junction ICS = Reverse-Saturation Current of B-C Junction IC = FIF – IR IE = IF - RIR IB = IE - IC IF = IES [exp(qVBE/kT) – 1] IR = IC [exp (qVBC/kT) – 1] If IES & ICS are not given, they can be determined using various BJT parameters. PHOTO TRANSSTOR • The phototransistor is a transistor in which base current is produced when light strikes the photosensitive semiconductor base region. • The collector-base P-N junction is exposed to incident light through a lens opening in the transistor package. • When there is no incident light, there is only a small thermally generated collector-to-emitter leakage current i.e. I(CEO), this is called the dark current and is typically in the nA range. When light strikes the collector-base pn junction, a base current is produced that is directly proportional to the light intensity. Since the actual photo generation of base current occurs in the collector-base region, the larger the physical area of this region, the more base current is generated. A phototransistor does not activated at every type of wave lengths of light. The phototransistor is similar to a regular BJT except that the base current is produced and controlled by light instead of a voltage source. The phototransistor effectively converts variations in light energy to an electrical signal The collector-base pn junction is exposed to incident light through a lens opening in the transistor package. The phototransistor is a transistor in which base current is produced when light strikes the photosensitive semiconductor base region. When there is no incident light, there is only a small thermally generated collector-to-emitter leakage current i.e. I(CEO), this is called the dark current and is typically in the range of nA. When light strikes the collector-base pn junction, a base current, Iλ, is produced that is directly proportional to the light intensity. This action produces a collector current that increases with Iλ . Except for the way base current is generated, the phototransistor behaves as a conventional BJT. In many cases there is no electrical connection to the base The relationship between the collector current and the light-generated base current in a phototransistor is IC = βDC * Iλ . 48 SYMBOL OF PHOTOTRANSISTOR A typical phototransistor is designed to offer a large area to the incident light, as the simplified structure diagram in Figure: Phototransistor are of two types. 1. 2. Three Lead Phototransistor. Two Lead Phototransistor. 1. Three Lead Phototransistor: In the three-lead configuration, the base lead is brought out so that the device can be used as a conventional BJT with or without the additional light-sensitivity feature. 2. Two Lead Phototransistor: In the two-lead configuration. the base is not electrically available, and the device can be used only with light as the input. In many applications, the phototransistor is used in the two-lead version. Phototransistor Bias Circuit Typical collector characteristic curves. Notice that each individual curve on the graph corresponds to a certain value of light intensity (in this case, the units are m W/cm2) and that the collector current increases with light intensity. Phototransistors are not sensitive to all light but only to light within a certain range of wavelengths. They are most sensitive to particular wavelengths. as shown by the peak of the spectral response curve in Figure. Key Points • Bipolar transistors are widely used in both analogue and digital circuits • They can be considered as either voltage-controlled or current-controlled devices • Their characteristics may be described by their gain or by their transconductance • Feedback can be used to overcome problems of variability • The majority of circuits use transistors in a common-emitter configuration where the input is applied to the base and the output is taken from the collector • Common-collector circuits make good buffer amplifiers • Bipolar transistors are used in a wide range of applications FET ( Field Effect Transistor) Few important advantages of FET over conventional Transistors 1. 2. Unipolar device i. e. operation depends on only one type of charge carriers (h or e) Voltage controlled Device (gate voltage controls drain current) 3. Very high input impedance (109-1012 ) 4. Source and drain are interchangeable in most Low-frequency applications 5. Low Voltage Low Current Operation is possible (Low-power consumption) Less Noisy as Compared to BJT No minority carrier storage (Turn off is faster) Self limiting device Very small in size, occupies very small space in ICs Low voltage low current operation is possible in MOSFETS Zero temperature drift of out put is possiblek 6. 7. 8. 9. 10. 11. Types of Field Effect Transistors (The Classification) » FET JFET n-Channel JFET p-Channel JFET MOSFET (IGFET) Enhancement MOSFET n-Channel EMOSFET p-Channel EMOSFET Depletion MOSFET n-Channel DMOSFET p-Channel DMOSFET The Junction Field Effect Transistor (JFET) Figure: n-Channel JFET. SYMBOLS Gate Gate Gate Source n-channel JFET Drain Drain Drain Source n-channel JFET Offset-gate symbol Source p-channel JFET Biasing the JFET Figure: n-Channel JFET and Biasing Circuit. Operation of JFET at Various Gate Bias Potentials Figure: The nonconductive depletion region becomes broader with increased reverse bias. (Note: The two gate regions of each FET are connected to each other.) Operation of a JFET Drain - N Gate P P + - + - N Source + Output or Drain (VD-ID) Characteristics of n-JFET Figure: Circuit for drain characteristics of the n-channel JFET and its Drain characteristics. Non-saturation (Ohmic) Region: The drain current is given by I DS Saturation (or Pinchoff) Region: I DS I DSS V2 P V V GS P 2 V 2I DSS V2 P V V DS P GS V2 V V DS V GS P DS 2 V V V DS P GS V GS and I I 1 DS DSS V P 2 Where, IDSS is the short circuit drain current, VP is the pinch off voltage Simple Operation and Break down of n-Channel JFET Figure: n-Channel FET for vGS = 0. N-Channel JFET Characteristics and Breakdown Break Down Region Figure: If vDG exceeds the breakdown voltage VB, drain current increases rapidly. VD-ID Characteristics of EMOS FET Locus of pts whereVDS VGS VP Saturation or Pinch off Reg. Figure: Typical drain characteristics of an n-channel JFET. Transfer (Mutual) Characteristics of n-Channel JFET V GS I I 1 DS DSS V P 2 IDSS VGS (off)=VP Figure: Transfer (or Mutual) Characteristics of n-Channel JFET JFET Transfer Curve This graph shows the value of ID for a given value of VGS Figure p-Channel FET circuit symbols. These are the same as the circuit symbols for n-channel devices, except for the directions of the arrowheads. Figure: Circuit symbol for an enhancement-mode n-channel MOSFET. Figure: n-Channel Enhancement MOSFET showing channel length L and channel width W. Figure: For vGS < Vto the pn junction between drain and body is reverse biased and iD=0. Figure: For vGS >Vto a channel of n-type material is induced in the region under the gate. As vGS increases, the channel becomes thicker. For small values of vDS ,iD is proportional to vDS. The device behaves as a resistor whose value depends on vGS. Figure: As vDS increases, the channel pinches down at the drain end and iD increases more slowly. Finally for vDS> vGS -Vto, iD becomes constant. Current-Voltage Relationship of n-EMOSFET Locus of points where Figure: Drain characteristics