Gummel–Poon model
Encyclopedia
The Gummel–Poon model is a model
of the bipolar junction transistor
. It was first described in a paper published by Hermann Gummel
and H. C. Poon at Bell Labs
in 1970.
The Gummel–Poon model and modern variants of it are widely used via incorporation in the popular circuit simulators known as SPICE
. A significant effect included in the Gummel–Poon model is the direct current
variation of the transistor
and 
. When certain parameters are omitted, the Gummel–Poon model reduces to the simpler Ebers–Moll model.
Transistor models
Transistors are simple devices with complicated behavior. In order to ensure the reliable operation of circuits employing transistors, it is necessary to scientifically model the physical phenomena observed in their operation using transistor models. There exists a variety of different models that...
of the bipolar junction transistor
Bipolar junction transistor
|- align = "center"| || PNP|- align = "center"| || NPNA bipolar transistor is a three-terminal electronic device constructed of doped semiconductor material and may be used in amplifying or switching applications. Bipolar transistors are so named because their operation involves both electrons...
. It was first described in a paper published by Hermann Gummel
Hermann Gummel
Hermann Gummel is a pioneer in the semiconductor industry.Gummel received his Diplom in physics from Philipps University in Marburg, Germany. He received his M.S. and Ph.D. degrees in physics from Syracuse University...
and H. C. Poon at Bell Labs
Bell Labs
Bell Laboratories is the research and development subsidiary of the French-owned Alcatel-Lucent and previously of the American Telephone & Telegraph Company , half-owned through its Western Electric manufacturing subsidiary.Bell Laboratories operates its...
in 1970.
The Gummel–Poon model and modern variants of it are widely used via incorporation in the popular circuit simulators known as SPICE
SPICE
SPICE is a general-purpose, open source analog electronic circuit simulator.It is a powerful program that is used in integrated circuit and board-level design to check the integrity of circuit designs and to predict circuit behavior.- Introduction :Unlike board-level designs composed of discrete...
. A significant effect included in the Gummel–Poon model is the direct current
Direct current
Direct current is the unidirectional flow of electric charge. Direct current is produced by such sources as batteries, thermocouples, solar cells, and commutator-type electric machines of the dynamo type. Direct current may flow in a conductor such as a wire, but can also flow through...
variation of the transistor
and . When certain parameters are omitted, the Gummel–Poon model reduces to the simpler Ebers–Moll model.Model parameters
Spice Gummel–Poon model parameters| # | Name | Property Modeled | Parameter | Units | Default Value |
|---|---|---|---|---|---|
| 1 | IS | current | transport saturation current | A | 1.00E-016 |
| 2 | BF | current | ideal max forward beta | ||
| 100 | |||||
| 3 | NF | current | forward current emission coefficient | ||
| 1 | |||||
| 4 | VAF | current | forward Early voltage | V | inf |
| 5 | IKF | current | corner for forward beta high current roll-off | A | inf |
| 6 | ISE | current | B-E leakage saturation current | A | 0 |
| 7 | NE | current | B-E leakage emission coefficient | ||
| 1.5 | |||||
| 8 | BR | current | ideal max reverse beta | ||
| 1 | |||||
| 9 | NR | current | reverse current emission coefficient | ||
| 1 | |||||
| 10 | VAR | current | reverse Early voltage | V | inf |
| 11 | IKR | current | corner for reverse beta high current roll-off | A | inf |
| 12 | ISC | current | B-C leakage saturation current | A | 0 |
| 13 | NC | current | B-C leakage emission coefficient | ||
| 2 | |||||
| 14 | RB | resistance | zero-bias base resistance | ohms | 0 |
| 15 | IRB | resistance | current where base resistance falls half-way to its minimum | A | inf |
| 16 | RBM | resistance | minimum base resistance at high currents | ohms | RB |
| 17 | RE | resistance | emitter resistance | ohms | 0 |
| 18 | RC | resistance | collector resistance | ohms | 0 |
| 19 | CJE | capacitance | B-E zero-bias depletion capacitance | F | 0 |
| 20 | VJE | capacitance | B-E built-in potential | V | 0.75 |
| 21 | MJE | capacitance | B-E junction exponential factor | ||
| 0.33 | |||||
| 22 | TF | capacitance | ideal forward transit time | s | 0 |
| 23 | XTF | capacitance | coefficient for bias dependence of TF | ||
| 0 | |||||
| 24 | VTF | capacitance | voltage describing VBC dependence of TF | V | inf |
| 25 | ITF | capacitance | high-current parameter for effect on TF | A | 0 |
| 26 | PTF | excess phase at freq=1.0/(TF*2PI) Hz | deg | 0 | |
| 27 | CJC | capacitance | B-C zero-bias depletion capacitance | F | 0 |
| 28 | VJC | capacitance | B-C built-in potential | V | 0.75 |
| 29 | MJC | capacitance | B-C junction exponential factor | ||
| 0.33 | |||||
| 30 | XCJC | capacitance | fraction of B-C depletion capacitance connected to internal base node | ||
| 1 | |||||
| 31 | TR | capacitance | ideal reverse transit time | s | 0 |
| 32 | CJS | capacitance | zero-bias collector-substrate capacitance | F | 0 |
| 33 | VJS | capacitance | substrate junction built-in potential | V | 0.75 |
| 34 | MJS | capacitance | substrate junction exponential factor | ||
| 0 | |||||
| 35 | XTB | forward and reverse beta temperature exponent | |||
| 0 | |||||
| 36 | EG | energy gap for temperature effect of IS | eV | 1.1 | |
| 37 | XTI | temperature exponent for effect of IS | |||
| 3 | |||||
| 38 | KF | flicker-noise coefficient | |||
| 0 | |||||
| 39 | AF | flicker-noise exponent | |||
| 1 | |||||
| 40 | FC | coefficient for forward-bias depletion capacitance formula | |||
| 0.5 | |||||
| 41 | TNOM | parameter measurement temperature | deg.C | 27 |
External links
- An Integral Charge Control Model of Bipolar Transistors manuscript
- Bell System Technical Journal, v49: i5 May-June 1970
- Summary of model with schematics and equations
- Agilent manual: The Gummel–Poon Bipolar Model as implemented in the simulator SPICE
- Designers-Guide.org comparison paper Xiaochong Cao, J. McMacken, K. Stiles, P. Layman, Juin J. Liou, Adelmo Ortiz-Conde, and S. Moinian, "Comparison of the New VBIC and Conventional Gummel–Poon Bipolar Transistor Models," IEEE Trans-ED 47 #2, Feb. 2000.
- The spice Gummel-Poon model online Course on modeling and simulation.