Common base Common emitter Common collector - …ee.sc.edu/personal/faculty/simin/elct563/21 bjt...

of 21/21
BJT Circuit Configurations R L V cc ~ ~ ~ R s v s V cc v s R s R L R L V cc R s v s Common base Common emitter Common collector V be
  • date post

    27-Aug-2018
  • Category

    Documents

  • view

    237
  • download

    0

Embed Size (px)

Transcript of Common base Common emitter Common collector - …ee.sc.edu/personal/faculty/simin/elct563/21 bjt...

  • BJT Circuit Configurations

    RL

    Vcc

    ~ ~ ~

    Rs

    vs

    Vcc

    vs

    Rs

    RLRL

    VccRs

    vs

    Common base Common emitter Common collector

    Vbe

  • Common emitter current gain

  • BJT Current-Voltage Characteristics

    Very small base current (~5-75 A) causes much higher collector current (up to 7.5 mA).The current gain is ~ 100

    VCE, V

  • VCE, V

    BJT amplifier circuit analysis: Operating point

    Collector current depends on two circuit parameters:the base current and the collector voltage.At high collector voltage the collector current depends on the base current only.For Ibase = 40 A, Icoll = 4 mA for any EC-E greater than 1.5 V

    RL

  • BJT amplifier circuit analysis: Operating point

    For an arbitrary collector voltage, collector current can be found using the KVL.The KVL for the collector emitter circuit, VCC = IRLRL + VCE;

    VCE, V

    CC CERL

    L

    V VIR

    = The RL current depends linearly on the collector voltage VCE

    Resistor RL and the C-E circuit of BJT are connected in series, hence IRL = ICFor Ib = 40 A and VCC = 13V, the collector current IC = 4 mAFor Ib = 75 A and VCC = 14V, the collector current IC = 4 mA

    VCE

    RL

    VCC

  • BJT amplifier gain analysis: 1

    1. Input circuitThe input voltage has two components: the DC bias and the AC signal

    Vin

    TimeDC bias

    AC signal amplitude

    DC voltage component biases the base-emitter p-n junction in the forward directionAC component is the input signal to be amplified by the BJT.

  • BJT amplifier gain analysis: 2

    2. Output circuitThe collector current has two components too.

    IC

    TimeDC current

    AC current amplitude

    DC and AC collector currents flow through the BJT in accordance with its I-V characteristics

    VCE, V

    Base current

  • BJT amplifier gain analysis: 3

    The resistance of the B-E junction is very low when VBE VBE0 Vbi 0.7 V. Hence the base current IB (Vin-VBE0)/R1 = (VinDC-VBE0+VinAC)/R1The collector current IC does not depend on the collector voltage if the latter is high enough.Hence, IC IB;The voltage drop across the load resistance R2: V2= IC R2;The output voltage Vout = VCC - V2 = VCC - IC R2;Vout = VCC - IC R2 = VCC - IB R2 = VCC - R2(VinDC-VBE0+VinAC)/R1;In signal amplifiers only AC component of the output voltage is important:

    VoutAC = - R2VinAC/R1;

    The amplifier voltage gain: kV = VoutAC/VinAC= - R2/R1;

    VCE, V

  • BJT amplifier gain analysis: 4

    Common emitter gain summary:

    Current gain: kI =

    Voltage gain: kV = VoutAC/VinAC= - R2/R1;

    Power gain: kP = kV kI = - 2 R2/R1

    VCE, V

  • BJT design and factors affecting the performance

  • Base resistance and emitter current crowding in BJTsThe voltage drop along the base layerVbb = rbb Ib,where rbb is called the base spreading resistance.

    1 1THVqV

    VkTS SI I e I e

    = =

    The length of the edge region, de, where most of the emitter current flows may be estimated from:

    The p-n junction current decreases rapidly when the voltage drops by Vbb ~ Vth = kT/q

    maxe

    th b b b be

    dV I R It W

    =

    de

  • Emitter current crowding in BJTs (cont.)

    1b

    b bqN

    =

    From these,

    th e the b b e b

    b b b

    V t W Vd q N t WI I

    =

    maxe

    th b b b be

    dV I R It W

    =

    de

  • the b b e b

    b

    Vd q N t WI

    Example

    Estimate the effective emitter length, de for the BJT having the following parameters:Ib = 50 A;Nb = 1017 cm-3

    b = 400 cm2/V-sWb = 0.1 m te = 100 m

    de = 3.33 e-4 cm = 3.33 m

    de

  • Large periphery B JT Design

  • Base narrowing (Early effect) The depletion width of the p-n junction depends on the applied voltage:

    (Here W is the depletion region widthnot the width of the base as in BJT!)

  • In the BJT, this effect means that the effective width of the base is less than Wb:Weff = Wb - Xdeb - Xdcbwhere Wb is the physical thickness of the base,xdeb and xdcb are the depletion region widths from the emitter and collector sides.The depletion widths are given by (Ne>>Nb):

    2/10 )(2

    =

    b

    bebideb Nq

    VVx

    2/1

    20 )(2

    +=

    b

    ccbbidcb

    qNNVV

    x

    xdcb is usually the most important factor since the voltage applied to collector is high.The doping level in collector, NDC has to be lower than that of the base, NAB, to reduce the Early effect:

    NC

  • Due to Early effect the effective base thickness depends on the collector voltage.

    In the gain expression, W should be replaced with Weff:

    The Early effect decreases the output resistance, and hence the voltage gain of BJTs.

    2

    22 p

    receff

    L

    W =

  • The punch-through breakdown voltage Vpt:

    Punch-through breakdown in BJTs -- the result of the Early effect

    W = xdcb( )

    c

    bcbpt N

    NNNWqV +=0

    2

    2

  • BJT Model Gummel-Poon model used in SPICE and other

    simulators

    Ie = Ic + Ib

    1c bI I

    =

    Hence,

    where is called a common base current gain

    Ie Ic

    Ib

    Applying KCL to the BJT terminals:

    Collector emitter current relationship:

    c eI I=

    ( )c c bI I I= +

    c bI I=Common emitter current gain is defined as:

    =

    1

    =

    1+

    The last two expressions link common emitter and common base current gains

  • Simplified Gummel-Poon BJT equivalent circuit

    Emitter junction:

    exp 1se bebeF F th

    I VIn V

    =

    Collector junction:

    exp 1sc bcbcR R th

    I VIn V

    =

    iIc nIe

    IcIe

    Base

    Emitter CollectorIdeal diode Ideal diode

    Leakage diodeLeakage diode

    Vth = kT/q = 0.026 V at 300 K

  • iIc nIe

    IcIe

    Base

    Emitter CollectorIdeal diode Ideal diode

    Leakage diodeLeakage diode

    Gummel-Poon BJT equivalent circuit accounting for the leakage currents

    Emitter base leakage diode:

    _ exp 1beLeak be seE th

    VI In V

    =

    Collector base leakage diode:

    _ exp 1bcLeak bc scC th

    VI In V

    =