CoolSPICE

CoolSPICE is a computer aided design tool for electronic circuit development. It is a version of the SPICE (Simulation Program with Integrated Circuit Emphasis) simulation tool with focuses on design and simulation for circuit operation at cryogenic temperatures, circuits operating with Wide-bandgap semiconductors, and simulation of thermal effects on circuit performance.

CoolSPICE
Stable release
ver5.2.1029.1122 / 2015
PlatformWindows
Available inEnglish
TypeElectronic circuit simulation
LicenseGNU Lesser General Public License 2.1
Websitecoolcadelectronics.com/coolspice/index.html

Introduction/Overview

The circuit simulation tool was developed from SPICE3f5,[1] a version of Ngspice, by CoolCAD Electronics, LLC.[2] It can model standard electronic applications, including radio frequency and audio circuits but was created with focus on modeling and designing circuits functioning at extreme temperatures ranging 4K to 300K. The software is used for modeling both cryogenic-temperature CMOS circuits[1][2] and high-power, high-temperature Silicon carbide (SiC)-power Metal Oxide Semiconductor Field Effect Transistor (MOSFET) devices as well.[3] Its also used to simulate the temperature change of the various electrical components that results from power dissipation during circuit operation.[4] A freeware version of CoolSPICE is available for download on the web.

Development and Capabilities

Cryogenic Electronics Simulation

CoolSPICE simulates electronic circuits operating at cryogenic temperatures ranging as low as 4K,[1] which is the temperature of liquid Helium (He). The compact models used to carry out these circuit simulations were created for numerous CMOS processes; models were built on BSIM 4 and experimentally verified.[2] BSIM 4 is a predictive MOSFET SPICE model for circuit simulation and CMOS development created by the BSIM Research Group in the Department of Electrical Engineering and Computer Sciences at the University of California, Berkeley.[5] CoolSPICE also has device models for cryogenic temperature operation simulation of NMOS and PMOS from different technologies. The tool reads net-list files of other similar circuit simulation tools, such as Cadence, as well.[1]

Silicon carbide Power MOSFET Device Simulation

CoolSPICE also has models for simulating Wide-bandgap semiconductor devices, which include power MOSFETs, SiC BJTs, and GaAs power FETs. The SPICE simulation models for SiC-power MOSFET devices for the software were developed using sub-circuits built around the standard BSIM MOSFET. Power devices have specific behaviors unique to themselves and in order to account for that factor, certain BSIM equations were modified. The drain-to-gate and drain-to-source capacitance terms were modified for the purpose of accounting for the different structure of power MOSFET devices. Due to these various modifications, the new BSIM equations required the introduction of new parameters to the already existing MOSFET parameter sets. The resulting new models with both common BSIM parameters as well the newly introduced parameters necessitated by the modifications, are the models used by CoolSPICE for simulations.[3][4][6]

Thermal Modeling

CoolSPICE is also used for performing thermal analysis of circuit operation. Due to Joule heating, electronic circuits generate heat and their components increase in temperature (fans are often used to help cool circuits under circumstances where temperature increase affects the electronics), and the software is able to simulate these types temperature increases. The heat transport mechanisms accounted for in these thermal calculations include conduction and convection. CoolSPICE contains a library for these thermal simulations.[4][6]

References

  1. Group, Techbriefs Media. "CoolSPICE: SPICE Simulator for Cryogenic Electronics – Nasa Tech Briefs :: NASA Tech Briefs". www.techbriefs.com. Retrieved 2016-06-01.
  2. Akturk, A., Potbhare, S., Booz, J., Goldsman, N., Gundlacha, D., Nandwanab, R., & Mayaramb, K. CoolSPICE: SPICE for Extreme Temperature Range Integrated Circuit Design and Modeling.
  3. Dilli, Z., Akturk, A., Goldsman, N., & Potbhare, S. (2015, September). An enhanced specialized SiC power MOSFET simulation system. In Simulation of Semiconductor Processes and Devices (SISPAD), 2015 International Conference on (pp. 463-466). IEEE.
  4. Akturk, A., Goldsman, N., & Potbhare, S. (2014, September). Electro-thermal simulation of silicon carbide power modules. In Simulation of Semiconductor Processes and Devices (SISPAD), 2014 International Conference on (pp. 237-240). IEEE.
  5. "BSIM Group » BSIM4". www-device.eecs.berkeley.edu. Retrieved 2016-06-01.
  6. Akturk, A., Goldsman, N., Dilli, Z., & Peggs, S. (2016). CoolSPICE: A New Electrical and Thermal Circuit Simulator for Power Circuit Design with New Wide Bandgap Device Capabilities ... Presentation, Applied Power Electronics Conference APEC.
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