Electronics Technology Fundamentals Chapter 19 Bipolar Junction Transistor Operation and Biasing.

Electronics Technology Fundamentals Chapter 19 Bipolar Junction Transistor Operation and Biasing

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 2 19.1 Introduction to Bipolar Junction Transistors – P1 Transistor – a three-terminal device whose output current, voltage, and/or power are controlled by its input Transistor Williamson Lab

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 3 19.1 Introduction to Bipolar Junction Transistors – P2 Transistor Currents – under normal circumstances, I C and I E vary directly with the value of I B

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 4 19.1 Introduction to Bipolar Junction Transistors – P3 Transistor Currents (Continued) Normally, I C is some multiple of I B Forward Current Gain – the factor by which current increases from base to the collector, represented by the Greek letter beta (β)

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 5 19.1 Introduction to Bipolar Junction Transistors – P4Bipolar Junction Transistors Transistor Voltages HyperPhysics

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 6 19.2 Transistor Construction and Operation – P1 Two pn Junctions Make Up Transistor Base-Emitter Junction Collector-Base Junction

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 7 19.2 Transistor Construction and Operation – P2 Transistor Junctions – normally operated in one of three biasing combinations Base-Emitter Junction Collector-Base Junction Operating Region Reverse biased Forward biased Reverse biased Forward biased Cutoff Active Saturation

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 8 19.2 Transistor Construction and Operation – P3 No Bias and Cutoff Biasing sources reverse bias both junctions causing wide depletion layers Only a small amount of reverse current flows

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 9 19.2 Transistor Construction and Operation – P4 Saturation Opposite of cutoff Further increases in I B do not cause an increase in I C

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 10 19.2 Transistor Construction and Operation – P5 Active Operation – the base-emitter junction is forward biased and the collector-base junction is reverse biased

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 12 19.3 Transistor Currents – P1 The Relationship Among I E, I C, and I B Kirchhoff’s Current Law – the current leaving a component must equal the current entering a component Since I B is much less than I C :

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 13 19.3 Transistor Currents – P2 DC Beta Ratio of the dc collector current to dc base current Typical Values: 50 to 300 Normally listed as dc current gain (h FE )

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 14 19.3 Transistor Currents – P3 DC Alpha – ratio of collector current to emitter current

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 15 19.3 Transistor Currents – P4 Collector Characteristic Curves – the relationship between I C and V CE at a specified value of I B

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 16 19.3 Transistor Currents – P5 Collector Characteristic Curves (Continued) – most amplifiers make use of the active region of operation (between V K and V BR )

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 17 19.3 Transistor Currents – P6 Collector Characteristic Curves (Continued) – Kirchhoff’s voltage law can be used to solve for V CE :

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 18 19.3 Transistor Currents – P7 Transistor Breakdown Occurs if V CE exceeds the breakdown rating of the transistor I C increases dramatically until the transistor is destroyed by excessive heat

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 19 19.4 Introduction to Transistor Biasing – P1 DC Biasing – used to set the initial values of I B, I C, and V CE for ac operation of the transistor DC Biasing

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 20 19.4 Introduction to Transistor Biasing – P2 The DC Load Line – a graph that represents every possible combination of I C and V CE

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 21 19.4 Introduction to Transistor Biasing – P3 The Q-Point The combination of I C and V CE on the dc load line where a transistor has no input signal Quiescent – at rest For linear operation, it is desirable to have the Q- point centered on the load line:

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 22 19.4 Introduction to Transistor Biasing – P4 The Q-Point (Continued) – an amplifier with a centered Q-point is said to be mid-point biased

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 23 19.5 Base Bias – P1 Base Bias (or Fixed Bias) – the simplest type of transistor biasing Base Bias

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 24 19.5 Base Bias – P2 Q-Point Shift – describes a condition where a change in transistor dc current gain (h FE ) causes a change in the Q-point values of I C and V CE

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 26 19.6 Voltage-Divider Bias – P1 Voltage-Divider Bias – the most commonly used transistor bias circuit (also known as universal bias) Voltage-Divider Bias

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 27 19.6 Voltage-Divider Bias – P2 The following equation assumes that the loading effect of the transistor on the voltage divider is negligible The loading effect can be significant in some cases

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 28 19.6 Voltage-Divider Bias – P3 Transistor Loading – When I 2 < 10I B, ignoring the loading effect of the transistor does introduce significant errors Base Input Resistance – Just as current increases by a factor of h FE from the base to emitter, R E is effectively increased by the same factor.

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 30 19.6 Voltage-Divider Bias – P5 Alternate (and more exact) approach to solving for I CQ and V CEQ

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 31 19.6 Voltage-Divider Bias – P6 Saturation and Cutoff Saturation, V CE = 0 V Cutoff

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 32 19.6 Voltage-Divider Bias – P7 Bias Stability The voltage-divider bias is a beta-independent circuit Values of I CQ and V CEQ are relatively stable against changes in beta (h FE )

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 33 19.6 Voltage-Divider Bias – P8 Bias Stability (Continued) I CQ = 1.46 mA for h FE = 50 I CQ = 1.56 mA for h FE = 100 Circuit experiences only a 6.8% increase in I CQ when h FE doubles in value

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 35 19.7 Other Transistor Biasing Circuits – P1 Emitter-Bias – consists of several resistors and a dual-polarity power supply Emitter-Bias

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 36 19.7 Other Transistor Biasing Circuits – P2 Emitter-Bias (Continued) Saturation Cutoff

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 38 19.7 Other Transistor Biasing Circuits – P4 Collector-Feedback Bias Obtains Q-point stability as a result of the base resistor connection to the collector (feedback) Feedback – used to describe a circuit that “feeds” a portion of the output voltage or current back to the input

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 39 19.7 Other Transistor Biasing Circuits – P5 Collector-Feedback Bias (Continued) Insert Figure 19.31

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 40 19.7 Other Transistor Biasing Circuits – P6 Collector-Feedback Bias (Continued) Q-Point Stability – based on the fact that I B and beta are inversely related

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 41 19.7 Other Transistor Biasing Circuits – P7 Emitter-Feedback Bias – same basic operation as the collector-feedback bias, except the emitter circuit affects the value of I B Insert Figure 19.33

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 43 19.8 Related Topics – P1 Transistor Specification Sheets Maximum Ratings Breakdown Voltage Ratings Insert Figure 19.37

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 44 19.8 Related Topics – P2 Transistor Specification Sheets (Continued) Maximum Ratings (Continued) Current – maximum allowable continuous value of I C - must be derated as temperature increases Power Dissipation (P D ) – must be derated as temperature increases Off Characteristics – describes operation in cutoff Collector Cutoff Current (I CEX ) – the maximum value of I C when the device is in cutoff Base Cutoff Current (I BL ) – the maximum base current present when the device is in cutoff

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 45 19.8 Related Topics – P3 Transistor Specification Sheets (Continued) On Characteristics – describes the dc operating characteristics for both the active and saturation regions of operation dc Current Gain (h FE ) – the value of dc beta (β dc ) Collector-Emitter Saturation Voltage (V CE(sat) ) – the value of V CE when the transistor is operated in saturation Base-Emitter Saturation Voltage (V BE(sat) ) – the value of V BE when the transistor is operated in saturation

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 47 19.8 Related Topics – P5 Transistor Testing (Continued)

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 48 19.8 Related Topics – P6 PNP Versus NPN Transistors

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 49 19.8 Related Topics – P7 Discrete Transistors Small-signal transistor (Example: 2N3904) – general, low power applications High-Voltage Transistors – used in circuits with high supply voltages. For example: television CRT control circuits High-Current Transistors – used in circuits with high current demands. For example: current regulator circuits High-Power Transistors – used in high-power circuits. For example: dc voltage regulators and stereo amplifier circuits

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 50 19.8 Related Topics – P8 Darlington Transistors Darlington Pair – a two- transistor configuration designed for high current gain Most often produced as a single component

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 51 19.8 Related Topics – P9 Darlington Transistors (Continued)

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 52 19.8 Related Topics – P10 Integrated Transistors Come in packages that house more than one transistor in integrated form Tend to have lower maximum power and current ratings than discrete transistors

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 53 19.8 Related Topics – P11 Surface-Mount Components (SMCs) Surface-Mount Much lighter and smaller than other types of components Mounted directly onto the surface of a PC board rather than into holes or fitted into IC sockets

Electronics Technology Fundamentals, 3 rd ed. Paynter and Boydell © 2009 Pearson Higher Education, Upper Saddle River, NJ 07458. All Rights Reserved. 54 19.8 Related Topics – P12 Surface-Mount Components (SMCs) (Continued)

Electronics Technology Fundamentals Chapter 19 Bipolar Junction Transistor Operation and Biasing.

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Electronics Technology Fundamentals Chapter 19 Bipolar Junction Transistor Operation and Biasing.

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