1. Introduction to Transistors Presented: October 23, 2001
Chris Green
Carl Hanna
Ancil Marshall
Kwame Ofori
2. Overview Introduction & History
Semiconductors
Operation of Transistors
Transistor Types
Applications
Examples
Questions
Conclusion
3. Background Invented at Bell Laboratories in 1947.
John Bardeen, Walter Brattain, and William Schockly received Nobel Prize in Physics in 1956 for Inventing Transistors.
First application: telephone signal amplification
Replaced cumbersome and inefficient vacuum tubes
Transistors can now be found on a single silicon wafer in most common electronic devices
4. Background Model of First Transistor
5. What are Transistors?
Versatile three lead semiconductor devices whose applications include electronic switching and modulation (amplification)
Transistors are miniature electronic switches.
Configuration of circuit determines whether the transistor will serve a switch and amplifier
Building blocks of the microprocessor, which is the brain of the computer.
Have two operating positions- on and off.
Binary functionality of transistors enables the processing of information in a computer.�
6. Semiconductors Silicon
Basic building material of most integrated circuits
Has four valence electrons, which allow it to form four covalent bonds.
Silicon crystal is an insulator-- no free electrons.
7. Semiconductors Resistance to current flow in the silicon crystal is reduced by adding small amounts of foreign impurities, which is referred to as doping.
Doping transforms a silicon crystal from a good insulator into a viable conductor; hence, the name semiconductor.
8. Semiconductors Two Dopant Types
N-type (Negative) –Free flowing electrons are added to the silicon crystal structure.
Examples include Group V elements including Phosphorous, Arsenic, and Antimony.
P-type(Positive)- Lack electrons and serve as potential slots for migrating electrons.
Examples include Group III elements such as Boron, Aluminum, and Gallium
9. Comparison of Energy Bands Semiconductor resembles an insulator, but with a smaller energy band.
Small energy band makes it a marginal conductor
10. Simple Semiconductors: Diodes Diode is the simplest semiconductor.
Allows current to flow in one direction only.
11. Diode Sign Conventions Power dissipated by a load = (+) quantity
Current flows from (+) ? (-)
Forward Biased
Supplied Current flows with natural (hole) diffusion current
Reversed Biased
Supplied Current fights against natural diffusion (hole) current and diode orientation
13. Reverse-Bias Example Charges cannot diffuse unless supplied current flows towards “n”
14. Diodes States Forward biased (on)- Current flows
Real: Need about 0.7 V to initiate electron-hole combination process.
Reversed biased (off)- Diode blocks current
Ideal- Current flow = 0
Real : Iflow= 10-6 Amps
15. Bipolar Junction Transistors (BJT) Three Layers in a BJT
Collector
Base (very thin)
has fewer doping atoms
Emitter
Two Types of BJT’s
PNP (figure on left)
operates with outgoing base current
NPN (figure on right)
operates with incoming base current
16. BJT Schematic Representation
17. BJT Operation Characteristics IC vs. VCE graph allows us to determine operating region.
Works for any IB or VCE
VBE tops out around ~0.7V
18. BJT Operation Regions
21. Active Linear NPN BJT
22. Possible Uses for BJT’s Can act as Signal Current Switch (Cutoff Mode)
Can act as Current Amplifier (Active Region)
Where:
Beta = intrinsic amp property (20 - 200)
23. FIELD-EFFECT TRANSISTORS In 1925, the fundamental principle of FET transistors was establish by Lilienfield.
In 1955, the first successful FET was made.
Types of Transistors
MOSFET (metal-oxide-semiconductor field-effect transistors)
JEFT (Junction Field-effect transistors)
24. MOSFET Four types:
n-channel enhancement mode
Most common since it is cheapest to manufacture
p-channel enhancement mode
n-channel depletion mode
p-channel depletion mode
25. MOSFET
26. MOSFET
27. n-channel Enhancement Mode Cutoff region
VGS < VT.
28. n-channel Enhancement Mode Ohmic region
VDS < 0.25 (VGS-VT), VGS>VT
Voltage controlled resistor.
29. n-channel Enhancement Mode Saturation region
VDS = VGS-VT, VGS > VT
Constant-current source.
30. Breakdown region
VDS > VB n-channel Enhancement Mode
31. Comparison p-type charge carrier.
Direction of drain current is opposite.
VDS and VGS are negative.
n-channel, p-channel behave the same way.
32. Depletion MOSFET Addition of an n-type region between the oxide layer and p-type substrate.
Thus, depletion MOSFETs are normally on.
VT, threshold voltage, is negative.
Unlike enhancement MOSFET, depletion MOSFET :
Allows positive and negative gate voltages.
Can be in the saturation region for VGS= 0
33. JFET JFET
n-channel
p-channel
34. JFET
35. JFET Cutoff region
VGS < -VP, -VP is the threshold voltage.
VDS = 0
36. JEFT Ohmic region
VDS < 0.25(VGS + VP), VGS > -VP.
Resistance controlled by VGS
37. JFET Saturation region
VDS = VGS +VP, VGS > -VP.
Constant- current source.
38. JFET Breakdown regions.
VDS > VB.
39. JFET
40. Use the I-V characteristic curves of BJT and MOSFET
Use the regions of operation of these transistors
BJT
Cutoff Region
Active Linear Region
Saturation Region
MOSFET
Cutoff Region
Ohmic or Triode Region
Saturation (Active Region) Transistors as Amplifiers and Switches
41. I-V Characteristic Curves
42. I-V Characteristic Curves
43. Transistors as Amplifiers
44. Transistors as Amplifiers
45. Transistors as Switches Basis of digital logic circuits
Used in microprocessors
Input to transistor gate can be analog or digital
Common names are
TTL – Transistor Transitor Logic
CMOS – Complementary Metal Oxide Semiconductor
46. Transistors as Switches – BJT Inverter
47. Transistors as Switches – BJT Inverter
48. Transistors as Switches- MOSFET
49. Transistors as Switches- MOSFET Inverter
50. Transistors as Switches- CMOS Inverter
51. References
