Modely tranzistorů technologie CMOS 0.35 um I3T pro PSpice / Models of transistors of CMOS 0.35 um process for PSpice

Veverka, Vojtěch

January 2014

The master’s thesis focuses on model designing of active components for PSpice simulator. Creation of models are based on text description, which is avaible in Cadence Spectre libraries. The aim of this thesis is approximate conversion of CMOS and bipolar tranzistors based on I3T 0.35 m technology. Simulation’s results and their comparation are discussed below.

SiC Readout IC for High Temperature Seismic Sensor System

Tian, Ye

January 2017

Over the last decade, electronics operating at high temperatures have been increasingly demanded to support in situ sensing applications such as automotive, deep-well drilling and aerospace. However, few of these applications have requirements above 460 °C, as the surface temperature of Venus, which is a specific target for the seismic sensing application in this thesis. Due to its wide bandgap, Silicon Carbide (SiC) is a promising candidate to implement integrated circuits (ICs) operating in such extreme environments. In this thesis, various analog and mixed-signal ICs in 4H-SiC bipolar technology for high-temperature sensing applications are explored, in which the device performance variation over temperatures are considered. For this purpose, device modeling, circuit design, layout design, and device/circuit characterization are involved. In this thesis, the circuits are fabricated in two batches using similar technologies. In Batch 1, the first SiC sigma-delta modulator is demonstrated to operate up to 500 °C with a 30 dB peak SNDR. Its building blocks including a fully-differential amplifier, an integrator and a comparator are characterized individually to investigate the modulator performance variation over temperatures. In the succeeding Batch 2, a SiC electromechanical sigma-delta modulator is designed with a chosen Si capacitive sensor for seismic sensing on Venus. Its building blocks including a charge amplifier, a multiplier and an oscillator are designed. Compared to Batch 1, a smaller transistor and two metal-interconnects are used to implement higher integration ICs in Batch 2. Moreover, the first VBIC-based compact model featured with continuous-temperature scalability from 27 to 500 °C is developed based on the SiC transistor in Batch 1, in order to optimize the design of circuits in Batch 2. The demonstrated performance of ICs in Batch 1 show the feasibility to further develop the SiC readout ICs for seismic sensor system operating on Venus. / <p>QC 20170911</p>

Silicon carbide (SiC)

bipolar junction transistor (BJT)

integrated circuit (IC)

sigma-delta (Σ∆)

data conversion

operational amplifier(OpAmp)

VBIC

SPICE Gummel-poon

high-temperature

electromechanical

accelerometer

capacitive sensor

Elektroteknik och elektronik