Closed-Loop kT/C Noise Cancellation for Sampling Circuits with Unprecedented Sensitivity — NSF Award to University of Texas at Dal
Thermal noise presents the most fundamental limit to the achievable signal-to-noise ratio (SNR) in analog electronic circuits. To suppress thermal noise, many scientific instruments used in fields such as radio astronomy, high-energy particle colliders, and emerging superconducting quantum computers require cryogenic c
| Award title | Closed-Loop kT/C Noise Cancellation for Sampling Circuits with Unprecedented Sensitivity |
|---|---|
| Award ID | 2519824 |
| Awardee | University of Texas at Dallas |
| City | RICHARDSON |
| State | TX |
| Amount obligated | $447,363 |
| Principal investigator | Yun Chiu |
| Program | CCSS-Comms Circuits & Sens Sys |
| Start date | 10/01/2025 |
| Abstract | Thermal noise presents the most fundamental limit to the achievable signal-to-noise ratio (SNR) in analog electronic circuits. To suppress thermal noise, many scientific instruments used in fields such as radio astronomy, high-energy particle colliders, and emerging superconducting quantum computers require cryogenic cooling, which significantly increases their cost and consumes more energy. For most commercial and industrial applications where cryogenic cooling is too expensive to employ, the o |
| Source | NSF Awards |
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