Your search keyword '"Richard P. Volant"' showing total 17 results

1. A Resonant Global Clock Distribution for the Cell Broadband Engine Processor

Author

S.C. Chan, P. Kapusta, Brian Flachs, John S. Liberty, S. Weitzel, Phillip J. Restle, J.S. Zimmerman, T.J. Bucelot, J. Keaty, and Richard P. Volant

Subjects

Engineering, business.industry, Underclocking, Clock rate, Electrical engineering, Clock gating, Digital clock manager, Clock network, Power (physics), Hardware_GENERAL, Electronic engineering, Electrical and Electronic Engineering, business, CPU multiplier, Jitter

Abstract

Resonant clock distributions have the potential to save power by recycling energy from cycle-to-cycle while at the same time improving performance by reducing the clock distribution latency and filtering out non-periodic noise. While these features have been successfully demonstrated in several small-scale experiments, there remained a number of concerns about whether these techniques would scale to a product application. By modifying the Cell broadband engine processor to incorporate a large resonant global clock network, power savings with full functionality is demonstrated over a 20% range in clock frequencies, and a 6-8 Watt power savings at 4 GHz. This was achieved by changing one wiring level and adding an additional thick copper level to create inductors and capacitors.

Published

2009

2. Product applications and technology directions with SiGe BiCMOS

Author

Robert A. Groves, David C. Ahlgren, David L. Harame, Gregory G. Freeman, P. Cooper, Dawn Wang, S.A.S.T Onge, Basanth Jagannathan, Ebenezer E. Eshun, Alvin J. Joseph, Jae-Sung Rieh, S. Subbanna, Douglas D. Coolbaugh, Kenneth J. Stein, V.S. Marangos, Jeffrey B. Johnson, J. Dunn, Vidhya Ramachandran, Richard P. Volant, and X. Wang

Subjects

Very-large-scale integration, Flexibility (engineering), Computer science, business.industry, Amplifier, Bipolar junction transistor, Electrical engineering, Heterojunction, Hardware_PERFORMANCEANDRELIABILITY, Integrated circuit design, BiCMOS, CMOS, Hardware_INTEGRATEDCIRCUITS, Electronic engineering, Electrical and Electronic Engineering, business, Uhf power amplifiers

Abstract

In this paper, we highlight the effectiveness and flexibility of SiGe BiCMOS as a technology platform over a wide range of performance and applications. The bandgap-engineered SiGe heterojunction bipolar transistors (HBTs) continue to be the workhorse of the technology, while the CMOS offering is fully foundry compatible for maximizing IP sharing. Process customization is done to provide high-quality passives, which greatly enables fully integrated single-chip solutions. Product examples include 40-Gb/s (OC768) components using high-speed SiGe HBTs, power amplifiers compatible for cellular applications, integrated voltage-controlled oscillators, and very high-level mixed-signal integration. It is argued that such key enablements along with the lower cost and higher yields attainable by SiGe BiCMOS technologies will provide competitive solutions for the communication marketplace.

Published

2003

3. 50–200 GHz Silicon–Germanium Heterojunction Bipolar Transistor BICMOS Technology and a Computer-Aided Design Environment for 2–50+ GHz Very Large-Scale Integration Mixed-Signal ICs

Author

James S. Dunn, Lawrence E. Larson, Peter Bacon, Huajie Chen, Robert A. Groves, Kathryn T. Schonenberg, James Mecke, K. Stein, Kevin H. Brelsford, David R. Greenberg, Seshadri Subbanna, David C. Ahlgren, Jae-Sung Rieh, Douglas D. Coolbaugh, Basanth Jagannathan, Shwu Jen Jeng, Mehmet Soyuer, Alvin J. Joseph, Richard P. Volant, Bernard S. Meyerson, Gregory G. Freeman, C. Dickey, David L. Harame, Mounir Meghelli, and D. A. Herman

Subjects

Very-large-scale integration, Physics and Astronomy (miscellaneous), business.industry, Computer science, Heterojunction bipolar transistor, General Engineering, Electrical engineering, General Physics and Astronomy, Mixed-signal integrated circuit, Hardware_PERFORMANCEANDRELIABILITY, BiCMOS, computer.software_genre, Silicon-germanium, chemistry.chemical_compound, Reliability (semiconductor), chemistry, Optical Carrier transmission rates, Hardware_INTEGRATEDCIRCUITS, Computer Aided Design, business, computer

Abstract

Silicon–germanium (SiGe) heterojunction bipolar transistor (HBT) BICMOS technology is a stable, ultra-high performance, semiconductor technology capable of supporting mixed-signal, very large-scale integration (VLSI) circuit designs for a variety of emerging communication applications. This technology is supported by a computer-aided design (CAD) system that supports a variety of high-performance circuit designs, mixed-signal circuit block reuse, and the ability to accurately predict circuit performance at the highest frequencies. This paper summarizes the progress this technology has made in recent years in moving from the research laboratory to a production environment. We also specifically address performance, operating voltage, reliability and integration considerations for using 100–200 GHz SiGe HBTs in high-speed (10–40 Gb/s) network ICs, an application space previously only addressed by InP technology. All indications are that SiGe will be very successful at addressing this new application space, and all facets of the networking IC market.

Published

2002

4. Microwave transformers, inductors and transmission lines implemented in an Si/SiGe HBT process

Author

D. Laney, J. Malinowski, David L. Harame, Lawrence E. Larson, M.G. Case, Seshadri Subbanna, P. Chan, and Richard P. Volant

Subjects

Radiation, Materials science, business.industry, Heterojunction bipolar transistor, Electrical engineering, Condensed Matter Physics, Inductor, Microstrip, Characteristic impedance, Q factor, Optoelectronics, Insertion loss, Electrical and Electronic Engineering, business, Microwave, Coupling coefficient of resonators

Abstract

Experimental results are presented on microwave inductors, transformers, and transmission lines fabricated in an Si/SiGe heterojunction-bipolar-transistor process with standard metallization and a thick polyimide dielectric. Microstrip transmission lines with characteristic impedances from 44 to 73 /spl Omega/, Q's from 10 to 14, and insertion losses from 0.11 to 0.16 dB/mm at 10 GHz are presented. Conventional planar inductors with inductances from 0.5 to 15 nH and with peak Q's up to 22 are presented. Lateral transformers with a maximum available gain of better than -5 dB and a measured coupling coefficient (k) of 0.6 at 5.5 GHz and 0.4 up to 12.5 GHz are also discussed.

Published

2001

5. Copper through silicon via (TSV) for 3D integration

Author

Norman Robson, S.S. Iyer, John M. Safran, Benjamin Himmel, G. LaRosa, Troy L. Graves-Abe, John W. Golz, F. Chen, William F. Landers, Kevin S. Petrarca, Timothy D. Sullivan, C. Kothandaraman, Mukta G. Farooq, Robert Hannon, Richard P. Volant, and Gary W. Maier

Subjects

Materials science, Through-silicon via, Silicon, business.industry, chemistry.chemical_element, Hardware_PERFORMANCEANDRELIABILITY, Thermal expansion, Reliability (semiconductor), CMOS, chemistry, Logic gate, Hardware_INTEGRATEDCIRCUITS, Electronic engineering, Optoelectronics, Hardware_ARITHMETICANDLOGICSTRUCTURES, business, Dram, High-κ dielectric

Abstract

Differential thermal expansion mismatch between Cu and Si along with high aspect ratios required for TSV pose unique challenges to the integration and reliability of Cu TSV. A TSV structure that successfully mitigates these concerns has been integrated into CMOS with high K/metal gates. Data from test structures demonstrate no ‘Cu pumping’ or other deleterious effects to neighboring devices or interconnects. Functional 3D prototypes utilizing stacked embedded DRAMs were demonstrated showing no impact from TSV processing.

Published

2012

6. 3D copper TSV integration, testing and reliability

Author

Michael J. Shapiro, Mukta G. Farooq, William F. Landers, Robert Hannon, Daniel Berger, S.S. Iyer, Troy L. Graves-Abe, F. Chen, R. Liptak, Kevin R. Winstel, Benjamin Himmel, Richard P. Volant, John M. Safran, P.S. Andry, Edmund J. Sprogis, Kevin S. Petrarca, Cornelia K. Tsang, Timothy D. Sullivan, and Chandrasekharan Kothandaraman

Subjects

Materials science, Integration testing, chemistry.chemical_element, Hardware_PERFORMANCEANDRELIABILITY, Temperature cycling, Copper, Reliability engineering, Stress (mechanics), Reliability (semiconductor), chemistry, Hardware_INTEGRATEDCIRCUITS, Electronic engineering, Degradation (geology), Hardware_ARITHMETICANDLOGICSTRUCTURES, Metal gate, Dram

Abstract

Node-agnostic Cu TSVs integrated with high-K/metal gate and embedded DRAM were used in functional 3D modules. Thermal cycling and stress results show no degradation of TSV or BEOL structures, and device and functional data indicate that there is no significant impact from TSV processing and/or proximity.

Published

2011

7. High-performance thick copper inductors in an RF technology

Author

W. Graham, David C. Ahlgren, James Vichiconti, Ronald W. Nunes, Michelle L. Steen, Kunal Vaed, Robert A. Groves, Richard P. Volant, Kenneth J. Stein, and Jae-Eun Park

Subjects

Materials science, business.industry, Integrated circuit, Inductor, Capacitance, law.invention, Surface micromachining, law, Q factor, Deep reactive-ion etching, Optoelectronics, Radio frequency, business, Telecommunications, Electronic circuit

Abstract

With the emergence of wired and wireless communication technologies, on-chip inductors find applications in a variety of high performance radio frequency (RF) circuits. In this work, we present two approaches for high-performance copper inductors in an RF technology. In the first approach (Type I), we lower ohmic losses to realize a high Q-factor. This is achieved by using, for the first time in a manufacturable technology, 4 μm thick copper spirals along with a 4 μm thick copper underpass on high-resistivity substrates (75 Ω-cm). The underpass is connected to the spirals with a 4 μm tall copper via, which lowers spiral to underpass capacitance. For further lowering the capacitive losses, an additional 6.1 μm thick interlayer dielectric separates the underpass from the substrate. In the second approach (Type II), we utilize a novel one-mask CMOS-compatible micromachining scheme to eliminate substrate losses. This is achieved by completely removing the silicon substrate from directly below the inductors. For a 1.1nH inductor, peak-Q shows an impressive two-fold improvement from 26.6 at 3.8 GHz for Type I inductor to 52.8 at 8.2 GHz for Type II inductor after silicon micromachining. The resonant frequency increases from 18 GHz to 27 GHz after substrate micromachining.

Published

2004

8. SiGe HBTs with cut-off frequency of 350 GHz

Author

Marwan H. Khater, David R. Greenberg, S.-J. Jeng, K. Stein, Jae-Sung Rieh, David C. Ahlgren, K. Vaed, John E. Florkey, Peter Andrew Smith, Seshadri Subbanna, H. Chen, David Angell, Anil K. Chinthakindi, Francois Pagette, Andreas D. Stricker, Richard P. Volant, F. Golan, Christopher M. Schnabel, Basanth Jagannathan, Gregory G. Freeman, and Kathryn T. Schonenberg

Subjects

Materials science, law, business.industry, Heterostructure-emitter bipolar transistor, Semiconductor materials, Transistor, Bipolar junction transistor, Optoelectronics, Simultaneous optimization, business, Cutoff frequency, law.invention

Abstract

This work reports on SiGe HBTs with f/sub T/ of 350 GHz. This is the highest reported f/sub T/ for any Si-based transistor as well as any bipolar transistor. Associated f/sub max/ is 170 GHz, and BV/sub CEO/ and BV/sub CBO/ are measured to be 1.4 V and 5.0 V, respectively. Also achieved was the simultaneous optimization of f/sub T/ and f/sub max/ resulting in 270 GHz and 260 GHz, with BV/sub CEO/ and BV/sub CBO/ of 1.6 V and 5.5 V, respectively. The dependence of device performance on bias condition and device dimension has been investigated. Considerations regarding the extraction of such high f/sub T/ and f/sub max/ values are also discussed.

Published

2003

9. Advanced passive devices for enhanced integrated RF circuit performance

Author

Dawn Wang, Jeffrey B. Johnson, Ebenezer E. Eshun, K. Watson, Douglas D. Coolbaugh, Robert A. Groves, D. Hararnel, Richard P. Volant, X. Wang, S. St Ongel, Kenneth J. Stein, S. Subbanna, A. Harnmad, Vidhya Ramachandran, and Z.X. He

Subjects

Materials science, business.industry, Electrical engineering, Inductor, Capacitance, law.invention, Capacitor, Voltage-controlled oscillator, law, Q factor, Radio frequency, Resistor, business, Varicap

Abstract

State of the art passive devices have been developed for optimum RF circuit performance. These devices include a hyperabrupt junction varactor with tunability (Cmax/Cmin) of 3.3, an accumulation mode MOS varactor, high capacitance nitride metal-insulator-metal capacitors, a BEOL TaN resistor and very high Q inductors with a peak Q of 28 at 3.5 GHz. VCO simulations using several of these elements show a significant reduction in VCO gain variation, phase noise, and power consumption.

Published

2003

10. The emerging role of SiGe BiCMOS technology in wired and wireless communications

Author

K. M. Newton, Richard P. Volant, Bernard S. Meyerson, V.S. Marangos, David L. Harame, Mete Erturk, Douglas D. Coolbaugh, Scott M. Parker, T. Tanji, Gregory G. Freeman, S. Subbanna, J. Dunn, C. Dickey, Alvin J. Joseph, H. Zamat, Kenneth J. Stein, Robert A. Groves, O. Schreiber, D. A. Herman, and Mark Doherty

Subjects

Space technology, Interconnection, Analogue electronics, business.industry, Computer science, Electrical engineering, Mixed-signal integrated circuit, Hardware_PERFORMANCEANDRELIABILITY, BiCMOS, Silicon-germanium, chemistry.chemical_compound, chemistry, Hardware_INTEGRATEDCIRCUITS, Electronic engineering, Wireless, Wired communication, business

Abstract

SiGe BiCMOS technology is well suited for both wired and wireless communication areas. For the wired space, the key requirements are very high speed active devices, extremely accurate interconnect modeling (lumped elements and transmission lines), and the ability to do very highly integrated analog and mixed signal chips. With data rates at 40 Gb/s, the distinction between digital and analog circuits becomes blurred and low frequency models are no longer adequate. RF/Analog layouts and models are needed for all active devices. SiGe BiCMOS satisfies all these requirements.

Published

2003

11. Using silicon-germanium mainstream BiCMOS technology for X-band and LMDS (25-30 GHz) microwave applications

Author

David R. Greenberg, Robert A. Groves, S. Subbanna, Gregory G. Freeman, Kenneth J. Stein, Richard P. Volant, B. Martin, D. A. Herman, David C. Ahlgren, Bernard S. Meyerson, and Basanth Jagannathan

Subjects

Materials science, business.industry, Heterojunction bipolar transistor, X band, Electrical engineering, ComputerApplications_COMPUTERSINOTHERSYSTEMS, Hardware_PERFORMANCEANDRELIABILITY, Silicon-germanium, chemistry.chemical_compound, chemistry, Hardware_INTEGRATEDCIRCUITS, Communications satellite, Local Multipoint Distribution Service, Optoelectronics, business, Monolithic microwave integrated circuit, Microwave, Electronic circuit

Abstract

The 0.18 /spl mu/m SiGe HBT BiCMOS technology we have developed has found a variety of uses in high-speed digital applications, up to 50 Gb/s (Freeman et al, 2001). This paper focuses on the use and applicability of this mainstream HBT BiCMOS technology for microwave applications, particularly X-band, satellite, and LMDS (20-30 GHz). We discuss the pros and cons relative to the well-known III-V MMIC technology, as well as Si microwave circuits on high-resistivity substrates (SIMMWICs) (Russer, 1998). It is shown that the SiGe BiCMOS technology is widely applicable to microwave technology, with examples such as filters, switches, and VCOs. We also review new technology developments that can be applied to the SiGe BiCMOS technology.

Published

2003

12. A 0.18 μm 90 GHz f/sub T/ SiGe HBT BiCMOS, ASIC-compatible, copper interconnect technology for RF and microwave applications

Author

Basanth Jagannathan, Kathryn T. Schonenberg, Gregory G. Freeman, David C. Ahlgren, J. Johnson, Robert A. Groves, G. Hugo, S. Subbanna, F. Huang, K. Stein, Richard P. Volant, S.-J. Jeng, and David R. Greenberg

Subjects

Materials science, Application-specific integrated circuit, CMOS, business.industry, Heterojunction bipolar transistor, Electrical engineering, Copper interconnect, Optoelectronics, BiCMOS, business, Monolithic microwave integrated circuit, Microwave applications, Common emitter

Abstract

We present a self-aligned, 0.18 /spl mu/m emitter width SiGe HBT with f/sub T/ of 90 GHz, f/sub MAX/ of 90 GHz (both at V/sub CB/=0.5 V), NF/sub MIN/ of 0.4 dB, and BV/sub CEO/ of 2.7 V. We also demonstrate that this device is integrable with IBM's 0.18 /spl mu/m, 1.8/3.3 V copper metallization CMOS technology with little effect on the CMOS device properties and design rules.

Published

2003

13. High Q inductors in a SiGe BiMOS process utilizing a thick metal process add-on module

Author

J. Malinowski, D. Jadus, Richard P. Volant, and Robert A. Groves

Subjects

Materials science, business.industry, Process (computing), Integrated circuit design, Inductor, Silicon-germanium, Metal, chemistry.chemical_compound, chemistry, visual_art, Q factor, Electronic engineering, visual_art.visual_art_medium, Optoelectronics, Radio frequency, business, Monolithic microwave integrated circuit

Abstract

Design tradeoffs for the optimization of inductor Q have been analyzed, and thick metallization has been identified as the most promising technology enhancement. Peak Qs approaching 19 have been demonstrated using thick metal.

Published

2003

14. Lateral microwave transformers and inductors implemented in a Si/SiGe HBT process

Author

D. Laney, Richard P. Volant, J. Malinowski, David L. Harame, S. Subbanna, Lawrence E. Larson, M. Case, and P. Chan

Subjects

Materials science, business.industry, Heterojunction bipolar transistor, Electrical engineering, Inductor, law.invention, Inductance, law, Q factor, Object-relational impedance mismatch, Optoelectronics, business, Transformer, Microwave, Coupling coefficient of resonators

Abstract

Experimental results are presented on a set of microwave inductors and transformers fabricated in a lateral spiral design utilizing two metal layers rather than a single metal layer as used in conventional planar magnetic devices. The fabrication process utilizes a production Si-SiGe HBT technology with standard metallization and a thick polyimide dielectric. Inductors with peak Q's between 2.6-5 and inductance values between 1-3 nH are presented. Transformers with a loss of less than 5 dB when corrected for impedance mismatch and a measured coupling coefficient (k) of 0.6 at 5.5 GHz and 0.4 up to 12.5 GHz are also discussed.

Published

2003

15. Low-loss microwave transmission lines and inductors implemented in a Si/SiGe HBT process

Author

M. Case, S. Subbanna, D. Laney, J. Malinowski, Richard P. Volant, P. Chan, David Harame, and Lawrence E. Larson

Subjects

Materials science, Silicon, business.industry, Heterojunction bipolar transistor, Electrical engineering, Process (computing), chemistry.chemical_element, Microwave transmission, Inductor, Line (electrical engineering), chemistry, Optoelectronics, Ohm, business, Electrical impedance

Abstract

Experimental results are presented on a set of microwave transmission line structures and planar inductors fabricated on a thick polyimide dielectric in a production Si/SiGe HBT technology using standard metallization. Microstrip transmission lines with characteristic impedances between 44-73 ohms, with losses at 10 GHz of 0.15 dB/mm and Q's between 10-14 are presented. Inductances between 0.5-15 nH with Q's up to 22 are also presented.

Published

2002

16. Prospects of silicon-germanium-based technology for very high-speed circuits

Author

Bernard S. Meyerson, Richard P. Volant, Jeffrey B. Johnson, D. A. Herman, S. Subbanna, Gregory G. Freeman, and Robert A. Groves

Subjects

Silicon, Computer science, business.industry, Heterojunction bipolar transistor, Bandwidth (signal processing), Electrical engineering, Silicon on insulator, chemistry.chemical_element, Hardware_PERFORMANCEANDRELIABILITY, Silicon-germanium, chemistry.chemical_compound, CMOS, chemistry, Gigabit, Hardware_INTEGRATEDCIRCUITS, business, Electronic circuit

Abstract

Silicon-germanium (SiGe) heterojunction bipolar transistor (HBT) BiCMOS technology has developed into a production manufacturing technology that replaces and extends the performance of silicon-based BiCMOS technology. The market impetus for this development has been the insatiable requirement for bandwidth in network communication at speeds up to 40 Gbit/s and the rapid growth of the global cellular and wireless LAN markets. There has also been much work on the use of silicon-based structures for microwave frequencies. This paper focuses on a review of the status of our SiGe BiCMOS technology, based on four generations of scaling CMOS-compatible SiGe. We also show in principle how techniques commonly used in Ill-V semiconductor technology and microwave systems can also be applied to SiGe chips, along with silicon-on-insulator (SOI) and other existing technology, to provide a possible further extension in SiGe performance, for 50+ GHz circuits.

Published

2002

17. Fabrication of high frequency passives on BiCMOS silicon substrates

Author

J. Malinowski, E. Begle, G. Sakamoto, Richard P. Volant, Robert A. Groves, P. Chan, Lawrence E. Larson, D. Laney, and S. Subbanna

Subjects

Materials science, Fabrication, Silicon, business.industry, Electrical engineering, chemistry.chemical_element, Integrated circuit, Substrate (electronics), BiCMOS, Microstrip, law.invention, chemistry, law, Optoelectronics, Wafer, business, Monolithic microwave integrated circuit

Abstract

We describe a manufacturable process for the fabrication of microwave passive circuits on a high loss silicon substrate. This process, known as "Topside" allows for the fabrication of high frequency microwave transmission lines and inductors over the typical final metal layer of an integrated circuit. This process has been implemented on 200 mm (8 inch) silicon wafers with SiGe HBT's and CMOS devices. We describe for the first time the process details, as well as microstrip data on different thicknesses of metal.

Published

2002