The MASTAR (Model for Analog Simulation of subThreshold, saturation and weak Avalanche Regions)[1][2]
is an analytical model of
Metal-Oxide Semiconductor Field-Effect Transistors, developed using the voltage-doping transformation (VDT) technique.[3][4][5][6] MASTAR offers good accuracy and continuity in current and its derivatives in all operation regimes of the
MOSFET devices. The model has been successfully used in CAD/
EDA simulation tools.[7]
The official ITRS definition of the acronym MASTAR is Model for Assessment of CMOSTechnologies And Roadmaps.[8] This software[9][10][11] is developed by
STMicroelectronics and is freely distributed on
ITRS organization web site.
^Skotnicki, T.; Merckel, G.; Denat, C. (1993). "MASTAR - A Model for Analog Simulation of Subthreshold, Saturation and Weak Avalanche Regions in MOSFETs". [Proceedings] 1993 International Workshop on VLSI Process and Device Modeling (1993 VPAD) (published May 14–15, 1993). pp. 146–147.
doi:
10.1109/VPAD.1993.724762.
ISBN0-7803-1338-0.
S2CID110860616.
^Skotnicki, T.; Denat, C.; Senn, P.; Merckel, G.; Hennion, B. (1994), "A new analog/digital CAD model for sub-halfmicron MOSFETs", Technical Digest., International Electron Devices Meeting (published December 11–14, 1994), pp. 165–168
^Skotnicki, T.; Marciniak, W. (1986), "A new approach to threshold voltage modelling of short-channel MOSFETS", Solid-State Electronics, vol. 29, no. 11 (published November 1986), pp. 1115–1127,
Bibcode:
1986SSEle..29.1115S,
doi:
10.1016/0038-1101(86)90054-7
^Skotnicki, T.; Merckel, G.; Pedron, T. (1988), "The voltage-doping transformation: a new approach to the modeling of MOSFET short-channel effects", IEEE Electron Device Letters, vol. 9, no. 3 (published March 1988), pp. 109–112,
Bibcode:
1988IEDL....9..109S,
doi:
10.1109/55.2058,
S2CID23596110
^Skotnicki, T.; Merckel, G.; Pedron, T. (1988), "A new punchthrough current model based on the voltage-doping transformation", IEEE Transactions on Electron Devices, vol. 35, no. 7 (published June 1988), pp. 1076–1086,
Bibcode:
1988ITED...35.1076S,
doi:
10.1109/16.3367
^Skotnicki, T.; Merckel, G.; Pedron, T. (1989), "Analytical study of punchthrough in buried channel p-MOSFETs", IEEE Transactions on Electron Devices, vol. 36, no. 4 (published April 1989), pp. 690–705,
Bibcode:
1989ITED...36..690S,
doi:
10.1109/16.22474
^Skotnicki, Tomasz; Boeuf, Frédéric (2004), "Optimal scaling methodologies and transistor performance", Published in Book "High Dielectric Constant Materials - VLSI MOSFET Applications" Edited by Howard R. Huff and David Gilmer Springer Series Microelectronics, vol. 16
^Skotnicki, Thomas; Hutchby, James A.; King, Tsu-Jae; Wong, H.-S. Philip; Boeuf, Frederic (2005), "The Road To The End Of Cmos Scaling", IEEE Circuits and Devices Magazine, vol. 21, no. 1 (published Jan–Feb 2005), pp. 16–26,
doi:
10.1109/MCD.2005.1388765,
S2CID6389553
^Skotnicki, Thomas; Fenouillet-Beranger, Claire; Gallon, Claire; Bœuf, Frederic; Monfray, Stephane; Payet, Fabrice; Pouydebasque, Arnaud; Szczap, Melanie; Farcy, Alexis; Arnaud, Franck; Clerc, Sylvain; Sellier, Manuel; Cathignol, Augustin; Schoellkopf, Jean-Pierre; Perea, Ernesto; Ferrant, Richard; Mingam, Hervé (2008), "Innovative materials devices and CMOS technologies for low-power mobile multimedia", IEEE Transactions on Electron Devices, vol. 55, no. 1 (published January 2008), pp. 96–130,
Bibcode:
2008ITED...55...96S,
doi:
10.1109/TED.2007.911338,
S2CID30700626
This technology-related article is a
stub. You can help Wikipedia by
expanding it.
The MASTAR (Model for Analog Simulation of subThreshold, saturation and weak Avalanche Regions)[1][2]
is an analytical model of
Metal-Oxide Semiconductor Field-Effect Transistors, developed using the voltage-doping transformation (VDT) technique.[3][4][5][6] MASTAR offers good accuracy and continuity in current and its derivatives in all operation regimes of the
MOSFET devices. The model has been successfully used in CAD/
EDA simulation tools.[7]
The official ITRS definition of the acronym MASTAR is Model for Assessment of CMOSTechnologies And Roadmaps.[8] This software[9][10][11] is developed by
STMicroelectronics and is freely distributed on
ITRS organization web site.
^Skotnicki, T.; Merckel, G.; Denat, C. (1993). "MASTAR - A Model for Analog Simulation of Subthreshold, Saturation and Weak Avalanche Regions in MOSFETs". [Proceedings] 1993 International Workshop on VLSI Process and Device Modeling (1993 VPAD) (published May 14–15, 1993). pp. 146–147.
doi:
10.1109/VPAD.1993.724762.
ISBN0-7803-1338-0.
S2CID110860616.
^Skotnicki, T.; Denat, C.; Senn, P.; Merckel, G.; Hennion, B. (1994), "A new analog/digital CAD model for sub-halfmicron MOSFETs", Technical Digest., International Electron Devices Meeting (published December 11–14, 1994), pp. 165–168
^Skotnicki, T.; Marciniak, W. (1986), "A new approach to threshold voltage modelling of short-channel MOSFETS", Solid-State Electronics, vol. 29, no. 11 (published November 1986), pp. 1115–1127,
Bibcode:
1986SSEle..29.1115S,
doi:
10.1016/0038-1101(86)90054-7
^Skotnicki, T.; Merckel, G.; Pedron, T. (1988), "The voltage-doping transformation: a new approach to the modeling of MOSFET short-channel effects", IEEE Electron Device Letters, vol. 9, no. 3 (published March 1988), pp. 109–112,
Bibcode:
1988IEDL....9..109S,
doi:
10.1109/55.2058,
S2CID23596110
^Skotnicki, T.; Merckel, G.; Pedron, T. (1988), "A new punchthrough current model based on the voltage-doping transformation", IEEE Transactions on Electron Devices, vol. 35, no. 7 (published June 1988), pp. 1076–1086,
Bibcode:
1988ITED...35.1076S,
doi:
10.1109/16.3367
^Skotnicki, T.; Merckel, G.; Pedron, T. (1989), "Analytical study of punchthrough in buried channel p-MOSFETs", IEEE Transactions on Electron Devices, vol. 36, no. 4 (published April 1989), pp. 690–705,
Bibcode:
1989ITED...36..690S,
doi:
10.1109/16.22474
^Skotnicki, Tomasz; Boeuf, Frédéric (2004), "Optimal scaling methodologies and transistor performance", Published in Book "High Dielectric Constant Materials - VLSI MOSFET Applications" Edited by Howard R. Huff and David Gilmer Springer Series Microelectronics, vol. 16
^Skotnicki, Thomas; Hutchby, James A.; King, Tsu-Jae; Wong, H.-S. Philip; Boeuf, Frederic (2005), "The Road To The End Of Cmos Scaling", IEEE Circuits and Devices Magazine, vol. 21, no. 1 (published Jan–Feb 2005), pp. 16–26,
doi:
10.1109/MCD.2005.1388765,
S2CID6389553
^Skotnicki, Thomas; Fenouillet-Beranger, Claire; Gallon, Claire; Bœuf, Frederic; Monfray, Stephane; Payet, Fabrice; Pouydebasque, Arnaud; Szczap, Melanie; Farcy, Alexis; Arnaud, Franck; Clerc, Sylvain; Sellier, Manuel; Cathignol, Augustin; Schoellkopf, Jean-Pierre; Perea, Ernesto; Ferrant, Richard; Mingam, Hervé (2008), "Innovative materials devices and CMOS technologies for low-power mobile multimedia", IEEE Transactions on Electron Devices, vol. 55, no. 1 (published January 2008), pp. 96–130,
Bibcode:
2008ITED...55...96S,
doi:
10.1109/TED.2007.911338,
S2CID30700626
This technology-related article is a
stub. You can help Wikipedia by
expanding it.