ghz dual chip for thz multiplier chains -...

THz Technology, Ultrafast Measurements, and Imaging A 260-340 GHz Dual Chip Frequency Tripler for THz Frequency Multiplier Chains Alain Maestrini (1 3) Charlotte Tripon-Canseliet (1), John S. Ward(2), John J. Gill (2) and Imran Mehdi (2) (1) Universite Pierre et Marie Curie - Paris 6, LISIF, 4 place Jussieu, case 252, 75252 Paris cedex 5, France Email: alain.maestriniglisif.jussieu.fr (2) Jet Propulsion Laboratory, California Institute of Technology, MS 168-314, 4800 Oak Grove Drive, Pasadena, CA 91109, USA (3) Observatoire de Paris, LERMA, 61 avenue de l'Observatoire, 75014 Paris, France. Abstract-We designed and fabricated a fix-tuned balanced frequency tripler working in the 260-340 GHz band to be the first stage of a x3x3x3 multiplier chain to 2.7 THz. The design of a dual-chip version of this multiplier featuring an input splitter / output combiner as part of the input / output matching networks of both chips - with no degradation of the expected bandwidth and efficiency- will be presented. I. INTRODUCTION Membrane technology enriched with beam-lead technology has opened new possibilities for frequency multipliers working at terahertz frequencies. The Jet Propulsion Laboratory (JPL) demonstrated in 2004-05 the first fully solid-state frequency tunable source able to pump a Hot Electron Bolometer (HEB) mixer at 1.9 THz [1] [2]. Frequency multipliers offer the advantage of working at room temperature and providing 7-15 % of electronically tunable bandwidth in the 1-2 THz region. To go beyond 2 THz, more drive power in the range 800-1200 GHz and subsequently in the range 250- 400 GHz is needed. The current work is aimed to create a wideband 300 GHz source to be used as a first stage of a x3x3x3 chain to 2.7 THz. II. SINGLE AND DUAL CHIP FREQUENCY TRIPLERS A. Single chipfrequency tripler design and results The tripler features multiple GaAs Schottky planar anodes in a balanced configuration integrated on a GaAs membrane. This tripler is similar to the 540-640 GHz tripler presented in [3]. The fabrication of the chip and the mechanical blocks was performed at JPL. Preliminary RF tests performed at JPL indicate that the multiplier covers the expected bandwidth and that the efficiency is in the range 1.5-7.5% with 100 mW of input power. B. Dual chipfrequency tripler design A dual-chip version of the 260-340 GHz tripler was designed using two identical chips to increase power handling capabilities. The output matching circuit of both chips integrates a classic Y-junction that acts as a combiner. Similarly, a Y-junction is used to evenly divide the input power. Fig. 1 shows a schematic of this multiplier. Simulations show that the dual-chip tripler should have the same bandwidth than the single-chip tripler with very similar efficiency. 200 mW In 86-114GHz 10 mW Out 260-340G Hz Figure 1. Configuration of the power combined triplers. REFERENCES [1] A. Maestrini, J. Ward, J. Gill, H. Javadi, E. Schlecht, G. Chattopadhyay, F. Maiwald, N.R. Erickson, and I. Mehdi, "A 1.7 to 1.9 THz Local Oscillator Source," IEEE Microwave and Wireless Components Letters, Vol. 14, no. 6, pp. 253-255, June 2004. [2] A. Maestrini, J. S. Ward, H. Javadi, C. Tripon-Canseliet, J. Gill, G. Chattopadhyay, E. Schlecht, and I. Mehdi, "Local Oscillator Chain for 1.55 to 1.75 THz with 100 iW Peak Power," IEEE Microwave and Wireless Components Letters, Vol. 15, no. 12, pp. 871-873, December 2005. [3] A. Maestrini, J. Ward, J. Gill, H. Javadi, E. Schlecht, C. Tripon- Canseliet, G. Chattopadhyay and I. Mehdi, "A 540-640 GHz High Efficiency Four Anode Frequency Tripler," IEEE Trans. Microwave Theory Tech, Vol. 53, pp. 2835 - 284, September 2005. 1-4244-0400-2/06/$20.00 ©2006 IEEE WedB1l-6 336

Upload: dinhduong

Post on 12-Sep-2018

213 views

Category:

Documents

0 download

Report

Download

Embed Size (px):

TRANSCRIPT

Page 1: GHz Dual Chip for THz Multiplier Chains - …aramis.obspm.fr/.../A-260-340GHz-Dual-Chip-Tripler-IRMMW-2006.pdf · Canseliet, G. Chattopadhyay and I. Mehdi, "A 540-640 GHz High Efficiency

THz Technology, Ultrafast Measurements, and Imaging

A 260-340 GHz Dual Chip Frequency Tripler for

THz Frequency Multiplier Chains

Alain Maestrini (1 3) Charlotte Tripon-Canseliet (1), John S. Ward(2), John J. Gill (2) and Imran Mehdi (2)

(1) Universite Pierre et Marie Curie - Paris 6, LISIF, 4 place Jussieu, case 252, 75252 Paris cedex 5, FranceEmail: alain.maestriniglisif.jussieu.fr

(2) Jet Propulsion Laboratory, California Institute of Technology,MS 168-314, 4800 Oak Grove Drive, Pasadena, CA 91109, USA

(3) Observatoire de Paris, LERMA, 61 avenue de l'Observatoire, 75014 Paris, France.

Abstract-We designed and fabricated a fix-tunedbalanced frequency tripler working in the 260-340 GHzband to be the first stage of a x3x3x3 multiplier chain to2.7 THz. The design of a dual-chip version of this multiplierfeaturing an input splitter / output combiner as part of theinput / output matching networks of both chips - with nodegradation of the expected bandwidth and efficiency- willbe presented.

I. INTRODUCTION

Membrane technology enriched with beam-leadtechnology has opened new possibilities for frequencymultipliers working at terahertz frequencies. The JetPropulsion Laboratory (JPL) demonstrated in 2004-05the first fully solid-state frequency tunable source able topump a Hot Electron Bolometer (HEB) mixer at 1.9 THz[1] [2]. Frequency multipliers offer the advantage ofworking at room temperature and providing 7-15 % ofelectronically tunable bandwidth in the 1-2 THz region.To go beyond 2 THz, more drive power in the range800-1200 GHz and subsequently in the range 250-400 GHz is needed. The current work is aimed to createa wideband 300 GHz source to be used as a first stage ofa x3x3x3 chain to 2.7 THz.

II. SINGLE AND DUAL CHIP FREQUENCY TRIPLERS

A. Single chipfrequency tripler design and resultsThe tripler features multiple GaAs Schottky planar

anodes in a balanced configuration integrated on a GaAsmembrane. This tripler is similar to the 540-640 GHztripler presented in [3]. The fabrication of the chip andthe mechanical blocks was performed at JPL.Preliminary RF tests performed at JPL indicate that themultiplier covers the expected bandwidth and that theefficiency is in the range 1.5-7.5% with 100 mW of inputpower.

B. Dual chipfrequency tripler designA dual-chip version of the 260-340 GHz tripler was

designed using two identical chips to increase powerhandling capabilities. The output matching circuit ofboth chips integrates a classic Y-junction that acts as acombiner. Similarly, a Y-junction is used to evenlydivide the input power. Fig. 1 shows a schematic of thismultiplier. Simulations show that the dual-chip triplershould have the same bandwidth than the single-chiptripler with very similar efficiency.

200 mW In86-114GHz

10 mW Out260-340GHz

Figure 1. Configuration ofthe power combined triplers.

REFERENCES

[1] A. Maestrini, J. Ward, J. Gill, H. Javadi, E. Schlecht, G.Chattopadhyay, F. Maiwald, N.R. Erickson, and I. Mehdi, "A 1.7to 1.9 THz Local Oscillator Source," IEEE Microwave andWireless Components Letters, Vol. 14, no. 6, pp. 253-255, June2004.

[2] A. Maestrini, J. S. Ward, H. Javadi, C. Tripon-Canseliet, J. Gill,G. Chattopadhyay, E. Schlecht, and I. Mehdi, "Local OscillatorChain for 1.55 to 1.75 THz with 100 iW Peak Power," IEEEMicrowave and Wireless Components Letters, Vol. 15, no. 12,pp. 871-873, December 2005.

[3] A. Maestrini, J. Ward, J. Gill, H. Javadi, E. Schlecht, C. Tripon-Canseliet, G. Chattopadhyay and I. Mehdi, "A 540-640 GHzHigh Efficiency Four Anode Frequency Tripler," IEEE Trans.Microwave Theory Tech, Vol. 53, pp. 2835 - 284, September2005.

WedB1l-6

336

GHz photonics on a Silicon Chip

AN923: EFR32 sub-GHz Matching Guide - Silicon Labs · AN923: EFR32 sub-GHz Matching Guide The EFR32 family of RFICs includes chip variants that provide 2.4 GHz-only operation, sub-GHz-only

A 2-GHz Direct Sampling ΔΣ Tunable Receiver with 40-GHz Sampling Clock and on-chip PLL

AWR6443, AWR6843 Single-Chip 60- to 64-GHz mmWave Sensor

2.6 GHz Receiver for On-Chip Optical Networking in 65nm ... · 2.6 GHz Receiver for On-Chip Optical Networking in 65nm CMOS Technology Letizia Fragomeni*, Fabio Agostino*, Alberto

AN930.1: EFR32 Series 1 2.4 GHz Matching Guide · 2020. 8. 14. · AN930.1: EFR32 Series 1 2.4 GHz Matching Guide The EFR32 devices include chip variants that provide 2.4 GHz-only

The DRS2 Chip: A 4.5 GHz Waveform Digitizing Chip for the MEG Experiment Stefan Ritt Paul Scherrer Institute, Switzerland

100-340GHz Spatially Multiplexed Communications: IC, … · [18], and such devices can offer 2-4 dB (device-level) noise figures at 140-340GHz. The more advanced R&D GaN HEMT technologies

A 1.5 GHz AWP Elliptic Curve Crypto Chip O. Hauck, S. A. Huss ICSLAB TU Darmstadt A. Katoch Philips Research A 1.5 GHz AWP Elliptic Curve Crypto Chip O

IWR6843, IWR6443 Single-Chip 60- to 64-GHz mmWave Sensor