Characterization and Modeling of SiC LTJFET for Analog Integrated Circuit Simulation and Design

IEEE Trans. Circuits Syst. I

2012

Self Cite

Superior performance of the Silicon Carbide (SiC) semiconductor in high temperature and harsh environment is widely known. However, utilizing the Vertical Channel 4H-SiC JFET (SiC JFET) for analog design exhibits significant design challenges, even at room temperature. The fundamental challenges are low intrinsic gain, the limitation of the Gate to Source Voltage Range (GSVR), and restrictions on utilizing Channel Length (CL) as a design parameter due to fabrication complexity. These challenges must be successfully overcome at room temperature, before moving towards high temperature design. The main objective of this paper is to establish a design base, overcome the challenges, demonstrate the feasibility, and present a novel all SiC JFET based operational amplifier (opamp) that addresses overall performance at room temperature. Before attempting design, Enhancement Mode (EM) and Depletion Mode (DM) SiC JFETs are characterized, analyzed, and modeled for simulation. A unique and reliable four stage opamp configuration is presented that takes design requirements into account, uses threshold voltage in place of CL as a design parameter, and employs gain enhancing design techniques while achieving maximum obtainable frequency response. The final opamp is fabricated and tested and shown to have 66.7 dB DC gain and 5.71 MHz unity gain frequency.

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“…(11) (12) As the number of cascoded transistors increases in Fig. 6(d) [14] through 6(f), higher output resistance can be observed.…”

Section: B Current Source Configurations and Characteristicsmentioning

confidence: 90%

Section: A Device Characteristics For Designmentioning

confidence: 96%

Section: A Device Characteristics For Designmentioning

confidence: 99%

“…6(a) to (f). Equations (9) through (12) show the overall output resistance of each configuration with respect to the transconductance and output resistance of the transistors.…”

Section: B Current Source Configurations and Characteristicsmentioning

confidence: 99%

See 2 more Smart Citations

The Design of an Operational Amplifier Using Silicon Carbide JFETs

IEEE Trans. Circuits Syst. I

2012

Self Cite

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“…1) are fabricated [3] in the form of Depletion Mode (DM) with negative threshold voltage (V th ) and Enhancement Mode (EM) with positive V th . Subsequently, they are characterized and modeled [4] from 27°C to 400°C. Both EM and DM devices that are used throughout the design share the same device structure and geometry, with the exception of different Finger Lengths (FLs).…”

Section: Devices and Characteristicsmentioning

confidence: 99%

Vertical Channel Silicon Carbide JFETs Based Operational Amplifiers

Pisano

2013

MSF

Superior performance of the Silicon Carbide (SiC) semiconductor in high temperature and harsh environment is widely known. However, utilizing the Vertical Channel 4H–SiC JFET (SiC VJFET) for analog circuit design exhibits significant design challenges, even at room temperature. The fundamental challenges are low intrinsic gain, the limitation of the Gate to Source Voltage Range (GSVR), and restrictions on utilizing Channel Length (CL) as a design parameter due to fabrication complexity. These challenges must be successfully overcome at room temperature, before moving forward with high temperature design. After addressing these issues, two operational amplifiers (opamps) with two distinct design topologies are designed and fabricated. The first design (opamp-1) emphasizes on the gain and Common Mode Rejection Ratio (CMRR) performances [1]. The second design (opamp-2) presents a novel opamp [2] with universal applications where the reliability and unity gain frequency performances are also improved. In this paper, the performance parameters of these two opamps along with their design topologies are reported and compared.

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Design of a Silicon Carbide JFET based operational amplifier for gain and CMRR performance

2009 IEEE International Symposium on Circuits and Systems

2009