A protection device is provided that exhibits a turn on time of order of one nanosecond or less. Such a device provides enhanced protection for integrated circuits against electrostatic discharge events. This in turn reduces the risk of device failure in use. The protection device can include a bipo
A protection device is provided that exhibits a turn on time of order of one nanosecond or less. Such a device provides enhanced protection for integrated circuits against electrostatic discharge events. This in turn reduces the risk of device failure in use. The protection device can include a bipolar transistor structure connected between a node to be protected and a discharge path.
대표청구항▼
1. An overvoltage protection device comprising: a bipolar transistor structure connected between a node to be protected and a discharge path, wherein the bipolar transistor structure comprises: a semiconductor layer;a base region in the semiconductor layer;a collector region in the semiconductor lay
1. An overvoltage protection device comprising: a bipolar transistor structure connected between a node to be protected and a discharge path, wherein the bipolar transistor structure comprises: a semiconductor layer;a base region in the semiconductor layer;a collector region in the semiconductor layer;an emitter region in the semiconductor layer, wherein the collector region and the emitter region are adjacent to one another, wherein the collector region, the base region, and the emitter region are configured to operate as a lateral bipolar transistor; anda field plate above a portion of the semiconductor layer between the collector region and the emitter region, wherein the field plate is electrically connected to the collector region, the emitter region, or the node to be protected. 2. The overvoltage protection device of claim 1, further comprising a substrate or a well doped with impurities to form a first region of semiconductor and a second region of semiconductor, wherein the substrate or the well comprises the semiconductor layer, wherein the first region includes the collector region and the second region includes the emitter region, wherein the field plate is insulated from the substrate or the well and extends substantially between the first and second regions. 3. The overvoltage protection device of claim 2, wherein the field plate is connected to the emitter region of the bipolar transistor structure, and a distance between the collector region and the emitter region is selectable to set a trigger voltage of the overvoltage protection device. 4. The overvoltage protection device of claim 2, wherein the field plate is connected to the collector region of the bipolar transistor structure or to the node to be protected, wherein a voltage applied to the field plate is operable to deplete the portion of the semiconductor layer between the collector region and the emitter region to form a channel within the bipolar transistor structure. 5. The overvoltage protection device of claim 1, further comprising a capacitor connected between the node to be protected and the base region of the bipolar transistor structure. 6. The overvoltage protection device of claim 5, where said capacitor has a value selected to initiate conduction in the bipolar transistor structure in response to an overvoltage event. 7. The overvoltage protection device of claim 5, in which the capacitor has a value greater that 40 pF. 8. The overvoltage protection device of claim 5 in which the capacitor has a value between 50 pF and 100 pF. 9. The overvoltage protection device of claim 1 further comprising at least one voltage clamping diode between the node to be protected and the discharge path. 10. The overvoltage protection device of claim 1, wherein a portion of the base region is disposed as a layer beneath the emitter region such that the base region has a nominal width of substantially 80 nm to 100 nm for a 40 Volt device. 11. The overvoltage protection device of claim 1, further comprising a resistor between the base region and the discharge path. 12. The overvoltage protection device of claim 1, further comprising a resistive and/or inductive path between the base region and the emitter region. 13. An overvoltage protection device comprising: a bipolar transistor structure comprising: a semiconductor layer;a collector region in the semiconductor layer;an emitter region in the semiconductor layer; anda base region in the semiconductor layer, the collector region being in a current flow path with a node to be protected from overvoltage events and with a discharge path, wherein the collector region, the base region, and the emitter region are configured to operate as a lateral bipolar transistor; anda capacitor connected between the base region and the node to be protected, wherein the capacitor injects charge into the base region in response to an overvoltage event so as to limit voltage overshoot. 14. The overvoltage protection device of claim 13, where said capacitor has a value selected to initiate conduction in the bipolar transistor structure in response to the overvoltage event. 15. The overvoltage protection device of claim 13, wherein the capacitor has a value greater that 40 pF. 16. The overvoltage protection device of claim 13, wherein the capacitor has a value between 50 pF and 100 pF. 17. The overvoltage protection device of claim 13 further comprising at least one voltage clamping diode between the node to be protected and the discharge path. 18. An overvoltage protection device comprising a transistor or silicon controlled rectifier in combination with at least one clamping diode, wherein the at least one clamping diode comprises: an N− epitaxial layer;an N region in the N− epitaxial layer; anda P+ region in the N region, wherein the P+ region and the N region operate as a vertical diode that undergoes impact ionization breakdown along a bottom of the P+ region. 19. The overvoltage protection device of claim 18, wherein a plurality of reverse based diodes are provided in parallel connected strings of series connected diodes to achieve a desired trigger voltage or a desired holding voltage and a desired resistance when conducting. 20. The overvoltage protection device of claim 18, wherein the at least one clamping diode further comprises a first conductor electrically connected to the N region and a second conductor electrically connected to the P+ region. 21. The overvoltage protection device of claim 18 wherein the transistor is a bipolar transistor structure connected between a node to be protected and a discharge path, wherein the bipolar transistor structure comprises a base region, a collector region, and an emitter region, wherein the collector region and the emitter region are adjacent to one another, wherein the collector region, the base region, and the emitter region are configured to operate as a lateral bipolar transistor. 22. The overvoltage protection device of claim 18 wherein the transistor is a field effect transistor (FET). 23. An overvoltage protection device, comprising a bipolar transistor structure connected between a node to be protected and a discharge path, wherein the bipolar transistor structure has a base region, a collector region, and an emitter region, wherein the base region comprises a first base region adjacent the collector region, but separated therefrom by an intermediate region of reduced doping concentration, such that a trigger voltage is set by the separation between the collector region and the first base region, wherein the base region further comprises a second base region vertically disposed with respect to the emitter region. 24. An overvoltage protection device as claimed in claim 23, wherein the base region is further connected to one or more of: a capacitor connected to the node to be protected;a capacitor connected to the collector;a resistor connected to the discharge path;an inductor connected to the discharge path;at least one diode arranged to conduct at a trigger voltage. 25. An overvoltage protection device as claimed in claim 24, wherein the base region is further connected to the at least one diode, wherein one or more of the at least one diode is a vertical diode. 26. An overvoltage protection device comprising a bipolar transistor connected between a node to be protected and a discharge path, wherein a base width of the bipolar transistor is selected such that a carrier transit time across a base of the bipolar transistor gives rise to a unity gain frequency (FT) value of the bipolar transistor where the inverse of the frequency is substantially equal to a predetermined rise time of an ESD event, and wherein the rise time is less than one nanosecond. 27. An overvoltage protection device comprising: a bipolar transistor connected between a node to be protected and a discharge path; anda clamping diode assembly in parallel with the bipolar transistor, wherein a diode on resistance and breakdown voltage are selected to reduce the clamping diode assembly size, wherein the clamping diode assembly comprises: an N− epitaxial layer;an N region in the N− epitaxial layer; anda P+ region in the N region, wherein the P+ region and the N region operate as a vertical diode that undergoes impact ionization breakdown along a bottom of the P+ region.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (106)
Salcedo, Javier A, Apparatus and method for electronic circuit protection.
Salcedo, Javier A.; Liou, Juin J.; Bernier, Joseph C.; Whitney, Donald K., Devices with adjustable dual-polarity trigger-and holding-voltage/current for high level of electrostatic discharge protection in sub-micron mixed signal CMOS/BiCMOS integrated circuits.
Tong, Paul C. F.; Wong, Siu-Weng Simon; Xu, Ping Ping; Liu, Zhi Qing; Chen, Wensong, Direct power-to-ground ESD protection with an electrostatic common-discharge line.
O\Neill Dennis P. (San Mateo County CA) Rempfer William C. (Santa Clara County CA) Dobkin Robert C. (Santa Clara County CA), Electrostatic discharge clamp using vertical NPN transistor.
Mergens, Markus Paul Josef; Russ, Cornelius Christian; Armer, John; Verhaege, Koen Gerard Maria, Electrostatic discharge protection structures for high speed technologies with mixed and ultra-low voltage supplies.
Davis Christopher K. ; Bajor George ; Beasom James D. ; Crandell Thomas L. ; Jung Taewon ; Rivoli Anthony L., High frequency analog transistors, method of fabrication and circuit implementation.
Beigel David F. (Swampscott MA) Krieger William A. (North Andover MA) Feindt Susan L. (Boston MA), Integrated circuit (IC) with a two-terminal diode device to protect metal-oxide-metal capacitors from ESD damage.
Beigel David F. (Swampscott MA) Wolfe Edward L. (North Andover MA) Krieger William A. (North Andover MA), Integrated circuit with diode-connected transistor for reducing ESD damage.
Clarke, David J; Salcedo, Javier Alejandro; Moane, Brian B; Luo, Juan; Murnane, Seamus; Heffernan, Kieran K; Twomey, John; Heffernan, Stephen Denis; Cosgrave, Gavin Patrick, Junction-isolated blocking voltage devices with integrated protection structures and methods of forming the same.
Wang Albert Z. H. ; Tsay Chen H. ; Deane Peter, Method for manufacturing a dual-direction over-voltage and over-current IC protection device and its cell structure.
Bendernagel Robert E. (Carmel NY) Kim Kyong-Min (Hopewell Junction NY) Silvestri Victor J. (Hopewell Junction NY) Smetana Pavel (Poughkeepsie NY) Strudwick Thomas H. (Wappingers Falls NY) White Willi, Method of manufacturing a semiconductor device structure employing a multi-level epitaxial structure.
Brown Jeffrey Scott ; Furkay Stephen Scott ; Gauthier ; Jr. Robert John ; Tian Xiaowei ; Tong Minh Ho ; Voldman Steven Howard, Semiconductor device fabrication method and apparatus using connecting implants.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.