Difference between revisions of "Brunn test"
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The focus of Analog IC Design projects is on designing analog circuits, simulations and layout. The applications cover a wide range: from high-speed transceivers to power management circuits, PLL design and bio-medical front-ends to name a few. | The focus of Analog IC Design projects is on designing analog circuits, simulations and layout. The applications cover a wide range: from high-speed transceivers to power management circuits, PLL design and bio-medical front-ends to name a few. | ||
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Revision as of 10:47, 5 December 2018
Analog IC Design
The focus of Analog IC Design projects is on designing analog circuits, simulations and layout. The applications cover a wide range: from high-speed transceivers to power management circuits, PLL design and bio-medical front-ends to name a few.
- High-Speed Digital-to-Analog Converter (DAC) for massive MIMO testing in 65nm CMOS
- High-Speed SAR ADC for next generation wireless communication in 12nm FinFET
- Analog building blocks for mmWave manipulation
- A mmWave Voltage-Controlled-Oscillator (VCO) for beyond 5G applications
- Bluetooth Low Energy network with optimized data throughput
- 5G Cellular RF Front-end Design in 22nm CMOS Technology
- Design of Charge-Pump PLL in 22nm for 5G communication applications
Biomedical System on Chips
Most projects are based around our bio-medical SoC called VivoSoC. It consists of specialised analogue front-ends (e.g. for ExG or neural signal acquisition, PPG based measurements, neural stimulation etc.) as well as powerful, PULP-based processor cores. Applications are in the field of optogenetics stimulation, ExG recordings (wearable and implantable), in-vivo and in-vitro experiments, neuroprosthetics etc.