Non-Linear Transistor (NLT) Library
MODELITHICS IS NOW HIRING FOR THE FOLLOWING POSITIONS:
RF Electronic Engineer – Component Modeling
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•Modelithics Transistor Modeling Technology
•Modelithics NLT Library - Version 3.0 Release Notes
The Modelithics NLT Non-Linear Transistor Library™ contains the industry's most advanced simulation models for transistors. These reliable, measurement-based models maximize the RF/MW electronic design automation (EDA) process, reduce design cycle times, and lower product development cost. The equivalent circuit models have been extracted from precision DV-IV, S-Parameter, gain, and noise measurements under various bias conditions across the given frequency range. High-power or low-noise amplifiers, oscillators - all the latest designs - can now be simulated with greater confidence than ever before.
Substrate Scalability
Many of Modelithics transistor models incorporate advanced features that fully account for substrate-related effects. Where applicable, substrate-scalable models are generated from mulitple sets of measurements, made with parts mounted on several fixtures using a variety of PCB materials, or multi-layer board thicknesses. The models are valid over a continuous range of substrate thicknesses and dielectric constants, bounded only by the H/Er range of the fixtures used during model measurements.
Accurate Noise Prediction
Modelithics low-power transistor models include accurate, measurement-validated noise simulation capability. Bias-dependent 1/f and noise parameter predictions enable rapid optimization of gain, match and noise performance. As a result, design trade-offs at the circuit and system level can be efficiently addressed, and the designs finalized much more quickly than before.
Temperature Effects
Carefully engineered transistor circuits are designed to reliably meet performance specifications over a range of environmental conditions. Modelithics models accurately simulate transistor performance at ambient temperature extremes, including self-heating effects. Potential design limitations can be identified and resolved before prototypes get to the temperature chamber.
Non-Linear Capability
State-of-the-art non-linear models accelerate the circuit design process when matched with advance simulation capabilities of today's EDA tools, including: accurate simulations of DC, small-signal and large-signal S-parameters, load-pull performance, harmonic balance, transient, envelope, noise, and complex modulation analyses.
FREE TRIAL
A time-limited installation of our libraries can be arranged for prospective customers who are ready to perform a full evaluation and approved by Modeltihics. Contact Modelithics, Inc. for more information.
| Vendor | Vendor Part Number | Modelithics Part Number | Device Type | Body Style | Output Power* | MVP / Example Data | Features |
| APT | AD1495-03 | Under Development | BJT | ||||
| Avago | ATF-501P8 | HMT-AGT-ATF501P8 | HEMT | LPCC | NL,NP,IM3 | ||
| Avago | ATF-511P8 | HMT-AGT-ATF511P8 | HEMT | LPCC | NL,NP,IM | ||
| Avago | AT-41511 | BJT-AGT-AT41511 | BJT | SOT143 | FL, NL, SS, TS | ||
| Avago | AT41533 | BJT-AGT-AT41533 | BJT | SOT23 | NL,SS,TS,NP | ||
| Avago | ATF35143 | HMT-AGT-ATF35143 | PHEMT | SOT343 | Linear, SS | ||
| Avago | ATF54143 | HMT-AGT-ATF54143 | PHEMT | SOT343 | IM, LP, NP, NL,SS | ||
| CEL | NE38018 | MES-CEL-NE38018 | MESFET | SOT343 | MVP Page | NL, NP, SS | |
| Excelics | EPA1200A | HMT-EXC-EPA1200A | PHEMT | 180 mil Metal Flange | NL | ||
| Freescale | MRF281 | MOS-FRS-MRF281 | LDMOSFET | Flange Mount | NL,SS,LP,IM3 | ||
| Fujitsu/Eudyna | FLL120MK | MES-FUJ-FLL120MK | MESFET | Flange Mount | NL,LP, TS | ||
| FLL800IQ | MESFET | IM, LP, NL | |||||
| Infineon | BFR949F | BJT-INF-BFP949 - *1 | BJT | TSFP-3 | NL,SS,TS | ||
| Infineon | BF999 | MOS-INF-BF999 | MOSFET | SOT23 | NL | ||
| Infineon | BFP420 | BJT-INF-BFP420 | BJT | SOT343 | NL,SS,TS,NP,FL | ||
| Microwave Technology | MwT-7 | MES-MWT-MWT7 | MESFET | Chip | NL | ||
| Mitsubishi | MGF4953A | HMT-MIT-MGF4953A-MIX | HMT | Ceramic | NL | ||
| Mitsubishi | MGF4953A | HMT-MIT-MGF4953A-AMP | HMT | Ceramic | NL, NP | ||
| Mitsubishi | RD01MUS1 | MOS-MIT-RD01MUS1 | MOSFET | SOT89 | NL,SS,TS,IM | ||
| Mitsubishi | RD07MVS1 | MOS-MIT-RD07MVS1 | MOSFET | SLP | NL,SS,LP | ||
| Motorola | MRF1513 | MOS-MOT-MRF1513 | MOSFET | CS466 | LP, NL | ||
| Motorola | MRF1570 | MOS-MOT-MRF1570T1 | MOSFET | CS1366 | LP, NL | ||
| NEC | NE3210S01 | HMT-NEC-NE3210S01 | PHEMT | S01 | MVP Page | NL,IM,NP | |
| NEC | NE350184C | HMT-NEC-NE350184C | PHEMT | S01 | MVP Page | NL,IM,NP | |
| NEC | NE68533 | BJT-NEC-NE68533 | BJT | SOT23 | MVP Page | NL,FL,SS | |
| NEC | NE68519 | BJT-NEC-NE68519 | BJT | 3pin Ultra super mini mold | MVP Page | NL,SS,TS,FL | |
| NEC | NE722S01 | MES-NEC-NE722S01 | MESFET | S01 | MVP Page | NL | |
| NEC | NESG3031M05 | HBT-NEC-NESG3031M05 | HBT | M05, 2012 | FL, NL, NP | ||
| NXP | BLF542 | MOS-PHL-BLF542 | LDMOS | SOT171A | NL | ||
| NXP | BF861B | JFT-PHL-BF861B | JFET | SOT23 | NL | ||
| NXP | BF862 | JFT-PHL-BF862 | JFT | SOT23 | NL | ||
| NXP | PBR941 | BJT-PHL-PBR941 | BJT | SOT23 | NL | ||
| NXP | BFS505 | BJT-PHL-BFS505 | BJT | SOT323 | NL,SS,IM,NP | ||
| NXP | BFS520 | BJT-PHL-BFS520 | BJT | SOT323 | NL | ||
| NXP | BFS540 | BJT-PHL-BFS540 | BJT | SOT323 | NL,SS,LP | ||
| NXP | BF1212 | DGMOS-PHL-BF1212 | DGMOS | SOT-143 | NL, NP, SS | ||
| NXP | BF1211 | DGMOS-PHL-BF1211 | DGMOS | SOT-143 | NL, NP, SS | ||
| ON Semi | MMB3904LT1 | BJT-ONS-MMBT3904LT1 | BJT | SOT23 | NL,TS | ||
| ON Semi | MMBFU310LT1 | JFT-ONS-MMBFU310LT1 | JFT | SOT23 | NL,TS,FL,NP | ||
| Rohm | UMT1NR | BJT-RHM-UMT1NR | BJT | SC-74 | NL | ||
| Sirenza | SLD-1083CZ | MOS-SRZ-SLD1083 | LDMOS | Ceramic | NL,IM,LP | ||
| Sirenza | SLD-2083CZ | MOS-SRZ-SLD2083 | LDMOS | Ceramic | NL,IM,LP |
•Modelithics Transistor Modeling Technology
•Modelithics NLT Library - Version 3.0 Release Notes