A study of Radiation-Tolerant Voltage-Controlled Oscillators designs in 65 nm bulk and 28 nm FDSOI CMOS technologies

Phase-locked loop (PLL) systems are widely employed in integrated circuits for space analog devices and communications systems that operate in radiation environments, where significant perturbations, especially in terms of phase noise, can be generated due to radiation particles. Among all the blocks that form a PLL system, previous research suggests the voltage-controlled oscillator (VCO) is one of the most critical components in terms of radiation tolerance and electric performance. Ring oscillators (ROs) and LC-tank VCOs have been commonly employed in high-performance PLLs. Nevertheless, both structures have drawbacks including a limited tuning range, high sensitivity to phase noise, limited radiation tolerance, and large design areas. In order to fulfill these high-performance requirements, a current-model logic (CML) based RO-VCO is presented as a possible solution capable of reducing the limitations of the commonly used structures and exploiting their advantages. The proposed hybrid VCO model includes passive components in its design which are the key parameters that define oscillation frequency of this structure. This tunable oscillator has been designed and tested in 65nm Bulk and 28 nm Fully depleted silicon-on-insulator (FDSOI) CMOS technologies The 65nm testchip was designed to compare the behavior of the proposed CML VCO with a current-starved RO and a radiation hardened by design (RHBD) LC-tank VCO in terms of tuning range, phase noise, Single event effect (SEE) sensitivity and design area. Simulations were carried out by applying a double exponential current pulse into different sensitive nodes of the three VCOs. In addition, SEE tests were conducted using pulsed laser experiments. Simulation and test results show that a CML VCO can effectively overcome the limitations presented by a RO-VCO and LC-tank VCO, achieving a wide range of tuning, and low sensitivity to noise and SEEs without the need for a large cross-section. Further studies of the proposed CML VCO were done on 28nm FDSOI in order to reduce the leakage current and increase the switching speed. the same current-starved VCO and CML VCO were implemented on this testchip, and simulations were performed by injecting a double exponential current pulse energy into the previously defined sensitive nodes. The results show SEE sensitivity improvement without narrowing the tuning range or affecting the phase noise response

Study of Single-Event Transient Effects on Analog Circuits

Radiation in space is potentially hazardous to microelectronic circuits and systems such as spacecraft electronics. Transient effects on circuits and systems from high energetic particles can interrupt electronics operation or crash the systems. This phenomenon is particularly serious in complementary metal-oxide-semiconductor (CMOS) integrated circuits (ICs) since most of modern ICs are implemented with CMOS technologies. The problem is getting worse with the technology scaling down. Radiation-hardening-by-design (RHBD) is a popular method to build CMOS devices and systems meeting performance criteria in radiation environment. Single-event transient (SET) effects in digital circuits have been studied extensively in the radiation effect community. In recent years analog RHBD has been received increasing attention since analog circuits start showing the vulnerability to the SETs due to the dramatic process scaling. Analog RHBD is still in the research stage. This study is to further study the effects of SET on analog CMOS circuits and introduces cost-effective RHBD approaches to mitigate these effects. The analog circuits concerned in this study include operational amplifiers (op amps), comparators, voltage-controlled oscillators (VCOs), and phase-locked loops (PLLs). Op amp is used to study SET effects on signal amplitude while the comparator, the VCO, and the PLL are used to study SET effects on signal state during transition time. In this work, approaches based on multi-level from transistor, circuit, to system are presented to mitigate the SET effects on the aforementioned circuits. Specifically, RHBD approach based on the circuit level, such as the op amp, adapts the auto-zeroing cancellation technique. The RHBD comparator implemented with dual-well and triple-well is studied and compared at the transistor level. SET effects are mitigated in a LC-tank oscillator by inserting a decoupling resistor. The RHBD PLL is implemented on the system level using triple modular redundancy (TMR) approach. It demonstrates that RHBD at multi-level can be cost-effective to mitigate the SEEs in analog circuits. In addition, SETs detection approaches are provided in this dissertation so that various mitigation approaches can be implemented more effectively. Performances and effectiveness of the proposed RHBD are validated through SPICE simulations on the schematic and pulsed-laser experiments on the fabricated circuits. The proposed and tested RHBD techniques can be applied to other relevant analog circuits in the industry to achieve radiation-tolerance

Radiation Tolerant Electronics, Volume II

Research on radiation tolerant electronics has increased rapidly over the last few years, resulting in many interesting approaches to model radiation effects and design radiation hardened integrated circuits and embedded systems. This research is strongly driven by the growing need for radiation hardened electronics for space applications, high-energy physics experiments such as those on the large hadron collider at CERN, and many terrestrial nuclear applications, including nuclear energy and safety management. With the progressive scaling of integrated circuit technologies and the growing complexity of electronic systems, their ionizing radiation susceptibility has raised many exciting challenges, which are expected to drive research in the coming decade.After the success of the first Special Issue on Radiation Tolerant Electronics, the current Special Issue features thirteen articles highlighting recent breakthroughs in radiation tolerant integrated circuit design, fault tolerance in FPGAs, radiation effects in semiconductor materials and advanced IC technologies and modelling of radiation effects

Phase Noise Analyses and Measurements in the Hybrid Memristor-CMOS Phase-Locked Loop Design and Devices Beyond Bulk CMOS

Phase-locked loop (PLLs) has been widely used in analog or mixed-signal integrated circuits. Since there is an increasing market for low noise and high speed devices, PLLs are being employed in communications. In this dissertation, we investigated phase noise, tuning range, jitter, and power performances in different architectures of PLL designs. More energy efficient devices such as memristor, graphene, transition metal di-chalcogenide (TMDC) materials and their respective transistors are introduced in the design phase-locked loop. Subsequently, we modeled phase noise of a CMOS phase-locked loop from the superposition of noises from its building blocks which comprises of a voltage-controlled oscillator, loop filter, frequency divider, phase-frequency detector, and the auxiliary input reference clock. Similarly, a linear time-invariant model that has additive noise sources in frequency domain is used to analyze the phase noise. The modeled phase noise results are further compared with the corresponding phase-locked loop designs in different n-well CMOS processes. With the scaling of CMOS technology and the increase of the electrical field, the problem of short channel effects (SCE) has become dominant, which causes decay in subthreshold slope (SS) and positive and negative shifts in the threshold voltages of nMOS and pMOS transistors, respectively. Various devices are proposed to continue extending Moore\u27s law and the roadmap in semiconductor industry. We employed tunnel field effect transistor owing to its better performance in terms of SS, leakage current, power consumption etc. Applying an appropriate bias voltage to the gate-source region of TFET causes the valence band to align with the conduction band and injecting the charge carriers. Similarly, under reverse bias, the two bands are misaligned and there is no injection of carriers. We implemented graphene TFET and MoS2 in PLL design and the results show improvements in phase noise, jitter, tuning range, and frequency of operation. In addition, the power consumption is greatly reduced due to the low supply voltage of tunnel field effect transistor

An Exploration of Radiation Effects on Low-Node, High-Speed, Mixed-Signal Integrated Circuits

As circuits decrease in size and increase in speed, there will be a push to use higher performance electronics in the space sector, military sector, and the energy sector. As technology nodes decrease, they typically become more sensitive to radiation effects so extra design techniques must be utilized in order to make the circuits immune to radiation effects. Single Event Effects (SEEs) are a major concern as they will upset the transient response of the system. Total Ionizing Dose (TID) effects are also a concern as they will degrade the performance of the device until failure over a long period of time. Voltage Controlled Oscillators (VCOs) and Phase-Locked Loops (PLLs) are critical in serial communication systems and must perform in the 10s of Gigahertz (GHz) range. This thesis focused on implementing a varactor scheme in order to reduce the sensitive area of the varactors inside of the VCO and implementing Triple Modular Redundancy in the digital blocks for the PLL to make it immune the Single Event Effects. A SEE analysis was done on both the VCO and PLL to ensure radiation tolerance along with measuring the overall electrical characteristics. The radiation hardened VCO was found to have a nominal tuning range of 14GHz to 17.7GHz with a Phase Noise performance of -124dBc/Hz. The PLL was found to have a total peak to peak jitter performance at a Q of 7.5 of approximately 400fs with a rms jitter of 40fs and deterministic jitter equal to approximately 200fs. The total power consumption is 20mW for the PLL and a total area of 0.046mm^2

Study of radiation-tolerant integrated circuits for space applications

Integrated Circuits in space suffer from reliability problems due to the radiative surroundings. High energy particles can ionize the semiconductor and lead to single event effects. For digital systems, the transients can upset the logic values in the storage cells which are called single event upsets, or in the combinational logic circuits which are called single event transients. While for analog systems, the transient will introduce noises and change the operating point. The influence becomes more notable in advanced technologies, where devices are more susceptive to the perturbations due to the compact layout. Recently radiation-hardened-by-design has become an effective approach compared to that of modifying semiconductor processes. Hence it is used in this thesis project. Firstly, three elaborately designed radiation-tolerant registers are implemented. Then, two built-in testing circuits are introduced. They are used to detect and count the single event upsets in the registers during high-energy particle tests. The third part is the pulse width measurement circuit, which is designed for measuring the single event transient pulse width in combinational logic circuits. According to the simulations, transient pulse width ranging from 90.6ps to 2.53ns can be effectively measured. Finally, two frequently used cross-coupled LC tank voltage-controlled oscillators are studied to compare their radiation tolerances. Simulation results show that the direct power connection and transistors working in the deep saturation mode have positive influence toward the radiation tolerance. All of the circuit designs, simulations and analyses are based on STMicroelectronics CMOS 90 nm 7M2T General Process

Advanced CMOS Integrated Circuit Design and Application

The recent development of various application systems and platforms, such as 5G, B5G, 6G, and IoT, is based on the advancement of CMOS integrated circuit (IC) technology that enables them to implement high-performance chipsets. In addition to development in the traditional fields of analog and digital integrated circuits, the development of CMOS IC design and application in high-power and high-frequency operations, which was previously thought to be possible only with compound semiconductor technology, is a core technology that drives rapid industrial development. This book aims to highlight advances in all aspects of CMOS integrated circuit design and applications without discriminating between different operating frequencies, output powers, and the analog/digital domains. Specific topics in the book include: Next-generation CMOS circuit design and application; CMOS RF/microwave/millimeter-wave/terahertz-wave integrated circuits and systems; CMOS integrated circuits specially used for wireless or wired systems and applications such as converters, sensors, interfaces, frequency synthesizers/generators/rectifiers, and so on; Algorithm and signal-processing methods to improve the performance of CMOS circuits and systems

Novel Current-Mode Sensor Interfacing and Radio Blocks for Cell Culture Monitoring

Since 2004 Imperial College has been developing the world’s first application-specific instrumentation aiming at the on-line, in-situ, physiochemical monitoring of adult stem cell cultures. That effort is internationally known as the ‘Intelligent Stem Cell Culture Systems’ (ISCCS) project. The ISCCS platform is formed by the functional integration of biosensors, interfacing electronics and bioreactors. Contrary to the PCB-level ISCCS platform the work presented in this thesis relates to the realization of a miniaturized cell culture monitoring platform. Specifically, this thesis details the synthesis and fabrication of pivotal VLSI circuit blocks suitable for the construction of a miniaturized microelectronic cell monitoring platform. The thesis is composed of two main parts. The first part details the design and operation of a two-stage current-input currentoutput topology suitable for three-electrode amperometric sensor measurements. The first stage is a CMOS-dual rail-class AB-current conveyor providing a low impedancevirtual ground node for a current input. The second stage is a novel hyperbolic-sinebased externally-linear internally-non-linear current amplification stage. This stage bases its operation upon the compressive sinh−1 conversion of the interfaced current to an intermediate auxiliary voltage and the subsequent sinh expansion of the same voltage. The proposed novel topology has been simulated for current-gain values ranging from 10 to 1000 using the parameters of the commercially available 0.8μm AMS CMOS process. Measured results from a chip fabricated in the same technology are also reported. The proposed interfacing/amplification architecture consumes 0.88-95μW. The second part describes the design and practical evaluation of a 13.56MHz frequency shift keying (FSK) short-range (5cm) telemetry link suitable for the monitoring of incubated cultures. Prior to the design of the full FSK radio system, a pair of 13.56MHz antennae are characterized experimentally. The experimental S-parameter-value determination of the 13.56MHz wireless link is incorporated into the Cadence Design Framework allowing a high fidelity simulation of the reported FSK radio. The transmitter of the proposed system is a novel multi-tapped seven-stage ring-oscillator-based VCO whereas the core of the receiver is an appropriately modified phase locked loop (PLL). Simulated and measured results from a 0.8μm CMOS technology chip are reported

Integrated Circuit Design for Radiation Sensing and Hardening.

Beyond the 1950s, integrated circuits have been widely used in a number of electronic devices surrounding people’s lives. In addition to computing electronics, scientific and medical equipment have also been undergone a metamorphosis, especially in radiation related fields where compact and precision radiation detection systems for nuclear power plants, positron emission tomography (PET), and radiation hardened by design (RHBD) circuits for space applications fabricated in advanced manufacturing technologies are exposed to the non-negligible probability of soft errors by radiation impact events. The integrated circuit design for radiation measurement equipment not only leads to numerous advantages on size and power consumption, but also raises many challenges regarding the speed and noise to replace conventional design modalities. This thesis presents solutions to front-end receiver designs for radiation sensors as well as an error detection and correction method to microprocessor designs under the condition of soft error occurrence. For the first preamplifier design, a novel technique that enhances the bandwidth and suppresses the input current noise by using two inductors is discussed. With the dual-inductor TIA signal processing configuration, one can reduce the fabrication cost, the area overhead, and the power consumption in a fast readout package. The second front-end receiver is a novel detector capacitance compensation technique by using the Miller effect. The fabricated CSA exhibits minimal variation in the pulse shape as the detector capacitance is increased. Lastly, a modified D flip-flop is discussed that is called Razor-Lite using charge-sharing at internal nodes to provide a compact EDAC design for modern well-balanced processors and RHBD against soft errors by SEE.PhDElectrical EngineeringUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttp://deepblue.lib.umich.edu/bitstream/2027.42/111548/1/iykwon_1.pd