On-chip Spiral Inductor/transformer Design And Modeling For Rf Applications

Passive components are indispensable in the design and development of microchips for high-frequency applications. Inductors in particular are used frequently in radio frequency (RF) IC\u27s such as low-noise amplifiers and oscillators. High performance inductor has become one of the critical components for voltage controlled oscillator (VCO) design, for its quality factor (Q) value directly affects the VCO phase noise. The optimization of inductor layout can improve its performance, but the improvement is limited by selected technology. Inductor performance is bounded by the thin routing metal and small distance from lossy substrate. On the other hand, the in-accurate inductor modeling further limits the optimization process. The on-chip inductor has been an important research topic since it was first proposed in early 1990\u27s. Significant amount of study has been accomplished and reported in literature; whereas some methods have been used in industry, but not released to public. It is of no doubt that a comprehensive solution is not exist yet. A comprehensive study of previous will be first address. Later author will point out the in-adequacy of skin effect and proximity effect as cause of current crowding in the inductor metal. A model method embedded with new explanation of current crowding is proposed and its applicability in differential inductor and balun is validated. This study leads to a robust optimization routine to improve inductor performance without any addition technology cost and development

Design of CMOS LC voltage controlled oscillators

This work presents the design and implementation of CMOS LC voltage controlled oscillators. On-chip planar spiral inductors and PMOS inversion mode varactors were utilized to implement the resonator. Two voltage controlled oscillators (VCOs) were realized as a part of this work, one designed to operate at 1.1 GHz while the second at 1.8 GHz. Both VCOs were implemented in a scalable digital CMOS process, with the former in a 1.5 micron CMOS process and the latter in a 0.5 micron technology. A simulation based methodology was adopted to arrive at a simple pi model used to model the metal and substrate related losses responsible for deteriorating the integrated inductor\u27s performance. Geometry based optimization techniques were utilized to arrive at an inductor geometry that ensures reasonable quality factor. In addition to the core VCO structure a host of test structures have been incorporated in order to carry out two-port network measurements in the future. Such measurements should enable one to gain a greater insight into the integrated inductor and varactor\u27s performance

CMOS On-Chip 3D Inductor Design & Application in RF Bio-Sensing

abstract: Three-dimensional (3D) inductors with square, hexagonal and octagonal geometries have been designed and simulated in ANSYS HFSS. The inductors have been designed on Silicon substrate with through-hole via with different width, spacing and thickness. Spice modeling has been done in Agilent ADS and comparison has been made with results of custom excel based calculator and HFSS simulation results. Single ended quality factor was measured as 12.97 and differential ended quality factor was measured as 15.96 at a maximum operational frequency of 3.65GHz. The single ended and differential inductance was measured as 2.98nH and 2.88nH respectively at this frequency. Based on results a symmetric octagonal inductor design has been recommended to be used for application in RF biosensing. A system design has been proposed based on use of this inductor and principle of inductive sensing using magnetic labeling.Dissertation/ThesisM.S. Electrical Engineering 201

Modeling of integrated inductors for RF circuit design

Dissertação para obtenção do Grau de Mestre em Engenharia Electrotécnic

Modeling and analysis of thick suspended deep x-ray liga inductors on CMOS/BiCMOS substrate

Modeling and simulation results for two types of 150 μm height air suspended inductors proposed for LIGA fabrication are presented. The inductor substrates used model the TSMC 0.18 μm CMOS/BiCMOS substrates. The RF performance between the suspended structure and the unsuspended counterpart are compared and the advantage of the suspended structures is explored. The potential of LIGA for fabricating high suspended inductors with good performance and for combining these with CMOS/BiCMOS is demonstrated

Integrated Silicon Microwave and Millimeterwave Passive Components and Functions

Non

Design of Wireless Power Transfer and Data Telemetry System for Biomedical Applications

With the advancement of biomedical instrumentation technologies sensor based remote healthcare monitoring system is gaining more attention day by day. In this system wearable and implantable sensors are placed outside or inside of the human body. Certain sensors are needed to be placed inside the human body to acquire the information on the vital physiological phenomena such as glucose, lactate, pH, oxygen, etc. These implantable sensors have associated circuits for sensor signal processing and data transmission. Powering the circuit is always a crucial design issue. Batteries cannot be used in implantable sensors which can come in contact with the blood resulting in serious health risks. An alternate approach is to supply power wirelessly for tether-less and battery- less operation of the circuits.Inductive power transfer is the most common method of wireless power transfer to the implantable sensors. For good inductive coupling, the inductors should have high inductance and high quality factor. But the physical dimensions of the implanted inductors cannot be large due to a number of biomedical constraints. Therefore, there is a need for small sized and high inductance, high quality factor inductors for implantable sensor applications. In this work, design of a multi-spiral solenoidal printed circuit board (PCB) inductor for biomedical application is presented. The targeted frequency for power transfer is 13.56 MHz which is within the license-free industrial, scientific and medical (ISM) band. A figure of merit based optimization technique has been utilized to optimize the PCB inductors. Similar principal is applied to design on-chip inductor which could be a potential solution for further miniaturization of the implantable system. For layered human tissue the optimum frequency of power transfer is 1 GHz for smaller coil size. For this reason, design and optimization of multi-spiral solenoidal integrated inductors for 1 GHz frequency is proposed. Finally, it is demonstrated that the proposed inductors exhibit a better overall performance in comparison with the conventional inductors for biomedical applications

The Performance of an Integrated Transformer in a DC/DC Converter

The separation between the low-voltage part and high-voltage part of the converter is formed by a transformer that transfers power while jamming the DC ring. The resonant mode power oscillator is utilized to allow elevated competence power transfer. The on-chip transformer is probable to have elevated value inductance, elevated quality factors and elevated coupling coefficient to decrease the loss in the oscillation. The performance of a transformer is extremely dependent on the structure, topology and other essential structures that create it compatible with the integrated circuits IC process such as patterned ground shield (PGS). Different types of transformers are modeled and simulated in MATLAB; the performances are compared to select the optimum design. The on-chip transformer model is simulated and the Results of MATLAB simulation are exposed, showing an excellent agreement in radio frequency RF

Master of Science

thesisThe purpose of this thesis was to determine if low-power switching power supplies can be made on-chip using integrated components. Integrated switching supplies are an emerging field that has followed the rise of systems-on-chip devices - especially in the biomedical field. Switching supply theory and implementation were examined systematically to determine the feasibility of such switching supplies. Classical switching power supply theory was presented first, including fundamental principles of operation and essential analysis techniques. Due to the unique constraints placed on integrated power supplies as a result of the small component size, the classical treatment had to be updated and modified. The result was a new methodology for calculating ripple current and voltage, circuit losses, and efficiency of switching supplies in both continuous and discontinuous conduction modes. Integrated and micro-scale switching supply components were then examined. Most importantly, the design of integrated inductors was discussed. Double-layer coils were found to be the best choice for integrated inductors with a small number of coils as they offered four times the inductance and only twice the resistance of similar single-layer coils. Six boards were tested using a variety of loads with manual switching cycle control. The test boards effectively modeled the behavior of integrated supplies and confirmed predictions about power loss and transfer. Using the test results and the equations previously derived, three test cases were simulated. The results were efficiencies of 75.16%, 75.09%, and 75.10% using 2 and 5 turn double spirals, and an external 120 nH coil, respectively. With these results, it should be possible to build integrated switching power supplies that meet or exceed the efficiency of linear supplies