Through-Silicon Vias in SiGe BiCMOS and Interposer Technologies for Sub-THz Applications

Im Rahmen der vorliegenden Dissertation zum Thema „Through-Silicon Vias in SiGe BiCMOS and Interposer Technologies for Sub-THz Applications“ wurde auf Basis einer 130 nm SiGe BiCMOS Technologie ein Through-Silicon Via (TSV) Technologiemodul zur Herstellung elektrischer Durchkontaktierungen für die Anwendung im Millimeterwellen und Sub-THz Frequenzbereich entwickelt. TSVs wurden mittels elektromagnetischer Simulationen modelliert und in Bezug auf ihre elektrischen Eigenschaften bis in den sub-THz Bereich bis zu 300 GHz optimiert. Es wurden die Wechselwirkungen zwischen Modellierung, Fertigungstechnologie und den elektrischen Eigenschaften untersucht. Besonderes Augenmerk wurde auf die technologischen Einflussfaktoren gelegt. Daraus schlussfolgernd wurde das TSV Technologiemodul entwickelt und in eine SiGe BiCMOS Technologie integriert. Hierzu wurde eine Via-Middle Integration gewählt, welche eine Freilegung der TSVs von der Wafer Rückseite erfordert. Durch die geringe Waferdicke von ca. 75 μm wird einen Carrier Wafer Handling Prozess verwendet. Dieser Prozess wurde unter der Randbedingung entwickelt, dass eine nachfolgende Bearbeitung der Wafer innerhalb der BiCMOS Pilotlinie erfolgen kann. Die Rückseitenbearbeitung zielt darauf ab, einen Redistribution Layer auf der Rückseite der BiCMOS Wafer zu realisieren. Hierzu wurde ein Prozess entwickelt, um gleichzeitig verschiedene TSV Strukturen mit variablen Geometrien zu realisieren und damit eine hohe TSV Design Flexibilität zu gewährleisten. Die TSV Strukturen wurden von DC bis über 300 GHz charakterisiert und die elektrischen Eigenschaften extrahiert. Dabei wurde gezeigt, dass TSV Verbindungen mit sehr geringer Dämpfung <1 dB bis 300 GHz realisierbar sind und somit ausgezeichnete Hochfrequenzeigenschaften aufweisen. Zuletzt wurden vielfältige Anwendungen wie das Grounding von Hochfrequenzschaltkreisen, Interposer mit Waveguides und 300 GHz Antennen dargestellt. Das Potential für Millimeterwellen Packaging und 3D Integration wurde evaluiert. TSV Technologien sind heutzutage in vielen Anwendungen z.B. im Bereich der Systemintegration von Digitalschaltkreisen und der Spannungsversorgung von integrierten Schaltkreisen etabliert. Im Rahmen dieser Arbeit wurde der Einsatz von TSVs für Millimeterwellen und dem sub-THz Frequenzbereich untersucht und die Anwendung für den sub-THz Bereich bis 300 GHz demonstriert. Dadurch werden neue Möglichkeiten der Systemintegration und des Packaging von Höchstfrequenzsystemen geschaffen.:Bibliographische Beschreibung List of symbols and abbreviations Acknowledgement 1. Introduction 2. FEM Modeling of BiCMOS & Interposer Through-Silicon Vias 3. Fabrication of BiCMOS & Silicon Interposer with TSVs 4. Characterization of BiCMOS Embedded Through-Silicon Vias 5. Applications 6. Conclusion and Future Work 7. Appendix 8. Publications & Patents 9. Bibliography 10. List of Figures and Table

De-embedding method for electrical response extraction of through-silicon via (TSV) in silicon interposer technology and signal integrity performance comparison with embedded multi-die interconnect bridge (EMIB) technology

Traditional two-dimensional system-in-package (2D SiP) can no longer support the scaling of size, power, bandwidth, and cost at the same rate required by Moore\u27s Law. Three-dimensional integrated circuits (3D-ICs), 2.5D silicon interposer technology in which through silicon vias are widely used, are implemented to meet these challenges. Embedded multi-die interconnect bridge (EMIB) technology are proposed as well. In Section 1, a novel de-embedding method is proposed for TSV characterization by using a set of simple yet efficient test patterns. Full wave models and corresponding equivalent circuits are provided to explain the electrical performance of the test patterns clearly. Furthermore, broadband measurement is performed for all test patterns up to 40 GHz, to verify the accuracy of the developed full wave models. Scanning Electron Microscopy (SEM) measurements are taken for all the test patterns to optimize the full wave models. Finally, the proposed de-embedding method is applied to extract the response of the TSV pair. Good agreement between the de-embedded results with analytical characterization and the full-wave simulation for a single TSV pair indicates that the proposed de-embedding method works effectively up to 40 GHz. In Section 2, the signal integrity performance of EMIB technology is evaluated and compared with silicon interposer technology. Two examples are available for each technology, one is simple with only one single trace pair considered; the other is complex with three differential pairs considered in the full wave simulation. Results of insertion loss, return loss, crosstalk and eye diagram are provided as criteria to evaluate the signal integrity performance for both technologies. This work provides guidelines to both top-level decision and specific IC or channel design --Abstract, page iii

Exploration and Design of Power-Efficient Networked Many-Core Systems

Multiprocessing is a promising solution to meet the requirements of near future applications. To get full benefit from parallel processing, a manycore system needs efficient, on-chip communication architecture. Networkon- Chip (NoC) is a general purpose communication concept that offers highthroughput, reduced power consumption, and keeps complexity in check by a regular composition of basic building blocks. This thesis presents power efficient communication approaches for networked many-core systems. We address a range of issues being important for designing power-efficient manycore systems at two different levels: the network-level and the router-level. From the network-level point of view, exploiting state-of-the-art concepts such as Globally Asynchronous Locally Synchronous (GALS), Voltage/ Frequency Island (VFI), and 3D Networks-on-Chip approaches may be a solution to the excessive power consumption demanded by today’s and future many-core systems. To this end, a low-cost 3D NoC architecture, based on high-speed GALS-based vertical channels, is proposed to mitigate high peak temperatures, power densities, and area footprints of vertical interconnects in 3D ICs. To further exploit the beneficial feature of a negligible inter-layer distance of 3D ICs, we propose a novel hybridization scheme for inter-layer communication. In addition, an efficient adaptive routing algorithm is presented which enables congestion-aware and reliable communication for the hybridized NoC architecture. An integrated monitoring and management platform on top of this architecture is also developed in order to implement more scalable power optimization techniques. From the router-level perspective, four design styles for implementing power-efficient reconfigurable interfaces in VFI-based NoC systems are proposed. To enhance the utilization of virtual channel buffers and to manage their power consumption, a partial virtual channel sharing method for NoC routers is devised and implemented. Extensive experiments with synthetic and real benchmarks show significant power savings and mitigated hotspots with similar performance compared to latest NoC architectures. The thesis concludes that careful codesigned elements from different network levels enable considerable power savings for many-core systems.Siirretty Doriast

Radiation safety based on the sky shine effect in reactor

In the reactor operation, neutrons and gamma rays are the most dominant radiation. As protection, lead and concrete shields are built around the reactor. However, the radiation can penetrate the water shielding inside the reactor pool. This incident leads to the occurrence of sky shine where a physical phenomenon of nuclear radiation sources was transmitted panoramic that extends to the environment. The effect of this phenomenon is caused by the fallout radiation into the surrounding area which causes the radiation dose to increase. High doses of exposure cause a person to have stochastic effects or deterministic effects. Therefore, this study was conducted to measure the radiation dose from sky shine effect that scattered around the reactor at different distances and different height above the reactor platform. In this paper, the analysis of the radiation dose of sky shine effect was measured using the experimental metho

Overcoming the Challenges for Multichip Integration: A Wireless Interconnect Approach

The physical limitations in the area, power density, and yield restrict the scalability of the single-chip multicore system to a relatively small number of cores. Instead of having a large chip, aggregating multiple smaller chips can overcome these physical limitations. Combining multiple dies can be done either by stacking vertically or by placing side-by-side on the same substrate within a single package. However, in order to be widely accepted, both multichip integration techniques need to overcome significant challenges. In the horizontally integrated multichip system, traditional inter-chip I/O does not scale well with technology scaling due to limitations of the pitch. Moreover, to transfer data between cores or memory components from one chip to another, state-of-the-art inter-chip communication over wireline channels require data signals to travel from internal nets to the peripheral I/O ports and then get routed over the inter-chip channels to the I/O port of the destination chip. Following this, the data is finally routed from the I/O to internal nets of the target chip over a wireline interconnect fabric. This multi-hop communication increases energy consumption while decreasing data bandwidth in a multichip system. On the other hand, in vertically integrated multichip system, the high power density resulting from the placement of computational components on top of each other aggravates the thermal issues of the chip leading to degraded performance and reduced reliability. Liquid cooling through microfluidic channels can provide cooling capabilities required for effective management of chip temperatures in vertical integration. However, to reduce the mechanical stresses and at the same time, to ensure temperature uniformity and adequate cooling competencies, the height and width of the microchannels need to be increased. This limits the area available to route Through-Silicon-Vias (TSVs) across the cooling layers and make the co-existence and co-design of TSVs and microchannels extreamly challenging. Research in recent years has demonstrated that on-chip and off-chip wireless interconnects are capable of establishing radio communications within as well as between multiple chips. The primary goal of this dissertation is to propose design principals targeting both horizontally and vertically integrated multichip system to provide high bandwidth, low latency, and energy efficient data communication by utilizing mm-wave wireless interconnects. The proposed solution has two parts: the first part proposes design methodology of a seamless hybrid wired and wireless interconnection network for the horizontally integrated multichip system to enable direct chip-to-chip communication between internal cores. Whereas the second part proposes a Wireless Network-on-Chip (WiNoC) architecture for the vertically integrated multichip system to realize data communication across interlayer microfluidic coolers eliminating the need to place and route signal TSVs through the cooling layers. The integration of wireless interconnect will significantly reduce the complexity of the co-design of TSV based interconnects and microchannel based interlayer cooling. Finally, this dissertation presents a combined trade-off evaluation of such wireless integration system in both horizontal and vertical sense and provides future directions for the design of the multichip system

INVESTIGATION OF TECHNIQUES FOR REDUCING UNINTENTIONAL ELECTROMAGNETIC EMISSIONS FROM ELECTRONIC CIRCUITS AND SYSTEMS

This dissertation describes three independent studies related to techniques for reducing unintentional electromagnetic emissions from electronic circuits and systems. The topics covered are: low-inductance multi-layer ceramic capacitor for high frequency circuit board decoupling, the application of imbalance difference model to various circuit board and cable geometries, and balanced cable interface for reducing common-mode currents from power inverter. The first chapter discusses the importance and the meaning of the connection inductance associated with MLCCs and analyzes the effect of plate orientation in MLCCs. It demonstrates that vertically oriented plates have no more or less inductance than horizontally oriented plates when the overall dimensions of the plate stack are similar. Decoupling capacitance options at the various levels of a high-speed circuit is investigated to determine the range of frequencies that decoupling at each level is likely to be is effective. Innovative low-inductance capacitive-stem capacitor configurations are described and their connection impedance is compared to that of standard surface-mounted capacitors. The second chapter investigates the imbalance difference model that is a method for modeling how differential-mode signal currents are converted to common-mode noise currents. Various cable geometries to determine how well imbalance factor`s values of DM-to-CM conversion compare to full-wave calculations are explored. The imbalance difference model can be applied to cables with more than two conductors are demonstrated. The third chapter investigates the balanced cable interface for reducing common-mode currents from power inverter. The concept of a balancing network to reduce the common-mode currents on power inverter cables above 30 MHz is introduced. An experimental test set-up is used to demonstrate the effect of a balancing network on the common-mode current, differential-mode current and the common-mode rejection ratio on a balanced cable with an imbalanced termination. The balancing network is also evaluated using a 3-phase brushless DC motor driver to verify its effectiveness in a real application

Addressing Manufacturing Challenges in NoC-based ULSI Designs

Hernández Luz, C. (2012). Addressing Manufacturing Challenges in NoC-based ULSI Designs [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/1669