Analog and Mixed Signal Design Group

The Analog and Mixed Signal Design Group is specialized in designing mixed signal integrated circuits and systems. The group divides into following research fields:

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.

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.

RF SoCs for the Internet of Things

High-Performance & V2X Cellular Communications

Available Projects

Analog IC Design

TimesADPLL: A power efficient wide loop bandwidth fractional-N all digital PLL

• Charge-Pump PLL with ring-oscillator based VCO in 65nm CMOS
• Bandgap voltage reference in 65nm CMOS
• DC-DC Buck converter in 65nm CMOS
• Low-Dropout Regulators for Magnetic Resonance Imaging
• Ultra-low power transceiver for implantable devices
• Inductive Charging Circuit for Implantable Devices
• Design of a 25 Gbps SerDes for optical chip-to-chip communication
• 5G Cellular RF Front-end Design in 28nm CMOS Technology
• High performance continuous-time Delta-Sigma ADC for magnetic resonance imaging
• Design of Charge-Pump PLL in 28nm for 5G communication applications
• High Performance Digitally-Assisted Time Domain ADC Design for DPLL used in Cellular IOT
• High Power Efficient Digitally Controlled Oscillator Design for Cellular IOT

Biomedical System on Chips

VivoSoC 3: A Multi-Sensor and Parallel Processing SoC for Miniaturised Medical Instrumentation

• Heart Rate Detection Algorithm
• Enabling Standalone Operation for a Mobile Health Platform
• Design and Implementation of a multi-mode multi-master I2C peripheral
• Optimal System Duty Cycling for a Mobile Health Platform
• Exploring Bio Impedance
• Android Software Design

RF SoCs for the Internet of Things

• VLSI Implementation of a 5G Ciphering Accelerator
• Design of an Ultra-Reliable Low-Latency Modem
• OTDOA Positioning for LTE Cat-M
• VLSI Implementation Polar Decoder using High Level Synthesis

High-Performance & V2X Cellular Communications

© Continental AG

• Machine Learning-based Compressive Sensing Vehicle Location Tracking ASIC Design
• Digital Front End Design & Frequency Offset Estimation for V2X Communications
• High-Throughput Channel Coding & Decoding for V2X Communications
• High-Speed Channel Estimation & Tracking for V2X Communications