Transistor history, working and principles
- 1. Transistors By A.Arputharaj Asst Professor Department of Electronics St.Jospehs College
- 2. Lecture Overview • What is a Transistor? • History • Types • Characteristics • Applications
- 3. What is a Transistor? • Semiconductors: ability to change from conductor to insulator • Can either allow current or prohibit current to flow • Useful as a switch, but also as an amplifier • Essential part of many technological advances
- 4. A Brief History • Guglielmo Marconi invents radio in 1895 • Problem: For long distance travel, signal must be amplified • Lee De Forest improves on Fleming’s original vacuum tube to amplify signals • Made use of third electrode • Too bulky for most applications
- 5. The Transistor is Born • Bell Labs (1947): Bardeen, Brattain, and Shockley • Originally made of germanium • Current transistors made of doped silicon
- 6. How Transistors Work • Doping: adding small amounts of other elements to create additional protons or electrons • P-Type: dopants lack a fourth valence electron (Boron, Aluminum) • N-Type: dopants have an additional (5th) valence electron (Phosphorus, Arsenic) • Importance: Current only flows from P to N
- 7. Diodes and Bias • Diode: simple P-N junction. • Forward Bias: allows current to flow from P to N. • Reverse Bias: no current allowed to flow from N to P. • Breakdown Voltage: sufficient N to P voltage of a Zener Diode will allow for current to flow in this direction.
- 8. • 3 adjacent regions of doped Si (each connected to a lead): – Base. (thin layer,less doped). – Collector. – Emitter. • 2 types of BJT: – npn. – pnp. • Most common: npn (focus on it). Bipolar Junction Transistor (BJT) npn bipolar junction transistor pnp bipolar junction transistor Developed by Shockley (1949)
- 9. • 1 thin layer of p-type, sandwiched between 2 layers of n-type. • N-type of emitter: 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). – There’s a depletion layer on the Base-Collector junction no flow of e- allowed. – BUT the Base is thin and Emitter region is n+ (heavily doped) electrons have enough momentum to cross the Base into the Collector. – The small base current IB controls a large current IC BJT NPN Transistor
- 10. • Current Gain: – α is the fraction of electrons that diffuse across the narrow Base region – 1- α is the fraction of electrons that recombine with holes in the Base region to create base current • The current Gain is expressed in terms of the β (beta) of the transistor (often called hfe by manufacturers). • β (beta) is Temperature and Voltage dependent. • It can vary a lot among transistors (common values for signal BJT: 20 - 200). BJT characteristics 1 ) 1 ( B C E B E C I I I I I I
- 11. • Emitter is grounded. • Base-Emitter starts to conduct with VBE=0.6V,IC flows and it’s IC=*IB. • Increasing IB, VBE slowly increases to 0.7V but 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) NPN Common Emitter circuit
- 12. Common Emitter characteristics No current flows Collector current controlled by the collector circuit. (Switch behavior) In full saturation VCE=0.2V. Collector current proportional to Base current The avalanche multiplication of current through collector junction occurs: to be avoided
- 13. Operation Region IB or VCE Char. BC and BE Junctions Mode Cutoff IB = Very small Reverse & Reverse Open Switch Saturation VCE = Small Forward & Forward Closed Switch Active Linear VCE = Moderate Reverse & Forward Linear Amplifier Break- down VCE = Large Beyond Limits Overload Operation region summary
- 14. BJT as Switch •Vin(Low ) < 0.7 V •BE junction not forward biased •Cutoff region •No current flows •Vout = VCE = Vcc •Vout = High •Vin(High) •BE junction forward biased (VBE=0.7V) •Saturation region •VCE small (~0.2 V for saturated BJT) •Vout = small •IB = (Vin-VB)/RB •Vout = Low
- 15. • Basis of digital logic circuits • Input to transistor gate can be analog or digital • Building blocks for TTL – Transistor Transistor Logic • Guidelines for designing a transistor switch: – VC>VB>VE – VBE= 0.7 V – IC independent from IB (in saturation). – Min. IB estimated from by (IBminIC/). – Input resistance such that IB > 5-10 times IBmin because varies among components, with temperature and voltage and RB may change when current flows. – Calculate the max IC and IB not to overcome device specifications. BJT as Switch 2
- 16. •Common emitter mode •Linear Active Region •Significant current Gain Example: •Let Gain, = 100 •Assume to be in active region -> VBE=0.7V •Find if it’s in active region BJT as Amplifier
- 17. BJT as Amplifier V V R I R I V V mA I I mA R R V V I I I I I V V BE E E C C CC CB B C E B BE BB B B C B E BE 93 . 3 7 . 0 ) 0107 . 0 * 101 )( 2 ( ) 07 . 1 )( 3 ( 10 * * 07 . 1 0107 . 0 * 100 * 0107 . 0 402 7 . 0 5 101 * ) 1 ( 7 . 0 VCB>0 so the BJT is in active region
- 18. References • www.lucent.com • http://transistors.globalspec.com • http://www.kpsec.freeuk.com • www.Howstuffworks.com • www.allaboutcircuits.com Thank u