Georgia Institute of Technology

Georgia Institute of Technology
ME 6405 Student Lecture Transistors Angela Sodemann Jin Yang Louis Nucci Wednesday, November 14, 2018 Georgia Institute of Technology

Lecture outline Brief History of Transistors Introduction to Transistors Bipolar Junction Transistors (BJT) Field Effect Transistors (FET) Power Transistors Georgia Institute of Technology

Transistor History Invention of transistors is a milestone of modern microelectronics industry Invention: 1947, at Bell Laboratories, by John Bardeen, Walter Brattain, and William Schockly (a three-point transistor, made with Germanium) 1956, They received Nobel Prize in Physics "for their researches on semiconductors and their discovery of the transistor effect" First application: replacing vacuum tubes (big & inefficient) Today: Advanced microprocessor uses as many as 1.7 billion transistors (MOSFETs) First model of Transistor Georgia Institute of Technology

Packaging Format of Transistor
Two main categories: Through-Hole Surface-Mount Packaging Materials: Glass, metal, ceramics or plastic Through-hole transistor Surface Mount Transistor Large transistor array uses latest Ball grid array (BGA) packaging Power transistors have large packages clamped to heat sinks for enhanced cooling Georgia Institute of Technology

What is Transistor ? Definition: Transistor is three-terminal, solid-state semiconductor device Function: Control electric current or voltage between two of the terminals by applying an electric current or voltage to third terminal. Transistor is an active component. Application: Switch in digital circuits Two operating positions: on and off. This switching capability allows binary functionality and permits to process information in a microprocessor Amplifier in analog circuits Georgia Institute of Technology

Transistor Chemistry Silicon Semiconductor that is able to be doped with other elements to adjust its electrical response Arsenic, phosphorous N-type dopants which add an electron to the silicon Boron, aluminum P-type dopants which have an extra “hole” Georgia Institute of Technology

PN Junction It is also called Junction Diode Allows current to flow from P to N only Electrons from n region diffuse to occupy holes in p region Thin depletion region forms near junction, resulting in contact potential (For silicon, on order of V) Two types of behavior: Forward and Reverse biased Georgia Institute of Technology

PN Junction – Forward Biased
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PN Junction – Reverse Biased

Types of Transistor Two Main Categories: Bipolar Junction Transistor - BJT Field Effect Transistor - FET JFET - Junction FET MOSFET - Metal Oxide Semiconductor FET Georgia Institute of Technology

BJT Georgia Institute of Technology

Bipolar Junction Transistor
npn bipolar junction transistor 3 adjacent doped regions (each layer connected to a lead) Base (B) Collector (C) Emitter (E) 2 types of BJT: npn pnp Most common type: npn pnp bipolar junction transistor Georgia Institute of Technology

npn BJT 1 thin layer of p-type silicon, sandwiched between 2 layers of n-type silicon Emitter is more heavily doped than collector With VC>VB>VE: Base-Emitter junction forward biased, Base-Collector reverse biased. Electrons diffuse from Emitter to Base (from n to p) Depletion layer on the Base-Collector junction no flow of electron allowed BUT Base is thin and Emitter region is heavily doped  electrons have enough momentum to cross Base into Collector Small base current IB controls large current IC, functioning as a current amplifier Georgia Institute of Technology

BJT Characteristics β (beta) is amplification factor for transistor (often called hFE by manufacturers) β is temperature and voltage dependent, no precise relationship can be assumed when designing transistor circuit β varies a lot among transistors (for typical BJT: on order of 100) IC is controlled by IB (Current Control) Georgia Institute of Technology

Common Emitter Transistor Circuit
Emitter is grounded and input voltage is applied to Base Base-Emitter starts to conduct when VBE is about 0.6V, IC flows with IC= β*IB As IB further increases, VBE slowly increases to 0.7V, IC rises exponentially As IC rises, voltage drop across RC increases and VCE drops toward ground (transistor in saturation, no more linear relation between IC and IB) Georgia Institute of Technology

Common Emitter Characteristics
Collector current IC proportional to Base current IB Collector current controlled by the collector circuit (Switch behavior) In full saturation VCE=0.2V No current flows Georgia Institute of Technology

Operation Point of BJT in Active Region
Every IB has corresponding I-V curve. Applying Kirchoff laws to base, emitter and collector circuits Load-line curve Biased Point Q Georgia Institute of Technology

Operation Region Summary
IB or VCE Char. Mode Cutoff IB = Very small Open Switch Saturation VCE = Small Closed Switch Active VCE = Moderate Amplifier Georgia Institute of Technology

BJT as Switch When Vin < 0.7V BE junction not forward biased Cutoff state of transistor IC=IE=0 Vout = VCE=VC Vout= High When Vin > 0.7 BE junction forward biased (VBE=0.7V) IB = (Vin-VB)/RB Saturation region VCE small (~0.2 V for saturated BJT) Vout= Low Georgia Institute of Technology

Practical Example – LED Switch
Transistor model is known: 2N3904 npn Assuming LED requires mA to provide a bright display and has 2 voltage drop when forwarded biased; When digital output is 0V, transistor is off When digital output is 5V, the transistor is in saturation, with base current Collector current (LED current) is limited by collector resistor LED is lighted Georgia Institute of Technology

BJT as Amplifier Assume Gain β = 100 Assume BJT in active region VBE=0.7V Georgia Institute of Technology

Practical Example – Speaker Amplifier

FET Georgia Institute of Technology

Field Effect Transistor
Described as a transconductance amplifier, meaning output current is controlled by an input voltage Contrarily, BJT is a current amplifier, a large output current is controlled by a much smaller base current In structure, FET is similar to BJT: Three terminals Different terminal names BJT Terminal FET Terminal Base Gate Collector Drain Emitter Source Georgia Institute of Technology

Types of Field Effect Transistor
Types of Field Effect Transistors MOSFET (metal-oxide-semiconductor field-effect transistors) Enhancement mode Depletion mode JFET (Junction Field-effect transistors) MESFET (Metal Semiconductor Field-effect transistor) HFET (Heterostructure Field-effect transistor) MODFET (Modulation Doped Field-effect transistor) Mostly used one is n-channel enhancement mode MOSFET, also called NMOS Conducting Region Nonconducting Region Nonconducting Region Enhanced n-MOSFET Depleted MOSFET JFET Georgia Institute of Technology

n-channel Enhancement Mode MOSFET
N-channel => Source and Drain are n type Enhancement mode => Increase VGS to make the travel from D to S easier for the electrons Georgia Institute of Technology

Modes of MOSFET Enhancement mode Sub-threshold – Vg < Vth Transistor is off Linear Region – Vg > Vth and Vds < Vgs-Vth Transistor is on Saturation – Vg > Vth and Vds > Vgs-Vth Transistor is on, with a portion of the channel being off Depletion mode Similar to enhancement, always on, use negative voltage Power mode Better behavior in saturation Georgia Institute of Technology

NMOS Characteristics Active region Saturation region For VDS > VPinchoff , the base current is a function of VGS Pinchoff Point Georgia Institute of Technology

NMOS Behavior VGS <Vth IDS=0 VGS > Vth : 0 < VDS < VPinch off Depletion mode (or active region), gate holes are repelled.  variable resistor (controled by VGS) VDS > VPinch off Inversion mode (or saturation region), IDS constant. VDS > VBreakdown IDS increases quickly Should be avoided Georgia Institute of Technology

Symbols of FET Georgia Institute of Technology

JFET Can be used with VG < 0 N-type N- doping is done by adding carrier electrons, phosphorus, arsenic, and antimony Georgia Institute of Technology

JFET Can be used with VG=0 P-Type P- doping is done by adding boron to silicon to create holes Georgia Institute of Technology

JFET Behavior Georgia Institute of Technology

Application of FET Switch Voltage Controlled Resistor Small Signal Amplifier Georgia Institute of Technology

Differences Between BJT and FET
Input current controls output current Input voltage controls output current Base, collector, emitter Gate, drain, source Cheaper More expensive Can be used as a variable resistor Georgia Institute of Technology

Power Transistor In General Power transistor is one that has a power dissipation of 1W or more Conduct a large maximum collector current and have maximum collector power dissipation Interface from low-output current devices such as IC and computer ports to other devices requiring large currents Generally shielded by or have a structure with heat sinks in order to dissipate more heat BJT Power Transistor FET Power Transistor Georgia Institute of Technology

Application of BJT Power Transistor
Used in LCD Inverter From Toshiba Semiconductor Company Georgia Institute of Technology

Application of BJT Power Transistor
Used in Battery Charger From Toshiba Semiconductor Company Georgia Institute of Technology

Application of MOSFET Power Transistor
Used in Battery Protection Circuit Georgia Institute of Technology

References David G. Alciatore and Michael B. Histand, “Introduction to Mechatronics and Measurement Systems”, Second Edition, Mc Graw Hill, 2002 Old student lecture slides Georgia Institute of Technology

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