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Mixed application MMIC technologies - Progress in combining RF, digital and photonic circuits (1991)

Mukherjee, S. ; Bendett, M. ; Sokolov, V. ; [et al.]

In: Other Sources

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Publication Date: 2011-08-24

Description: Approaches for future 'mixed application' monolithic integrated circuits (ICs) employing optical receive/transmit, RF amplification and modulation and digital control functions are discussed. We focus on compatibility of the photonic component fabrication with conventional RF and digital IC technologies. Recent progress at Honeywell in integrating several parts of the desired RF/digital/photonic circuit integration suite required for construction of a future millimeter-wave optically-controlled phased-array element are illustrated.

Keywords: ELECTRONICS AND ELECTRICAL ENGINEERING

Type: In: Monolithic microwave integrated circuits for sensors, radar, and communications systems; Proceedings of the Meeting, Orlando, FL, Apr. 2-4, 1991 (A93-25776 09-33); p. 223-230.

Format: text

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A 30 GHz monolithic receive module technology assessment (1988)

Bauhahn, P. ; Sokolov, V. ; Geddes, J. ; [et al.]

In: CASI

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Publication Date: 2019-06-28

Description: This report is a technology assessment relevant to the 30 GHz Monolithic Receive Module development. It is based on results obtained on the present NASA Contract (NAS3-23356) as well as on information gathered from literature and other industry sources. To date the on-going Honeywell program has concentrated on demonstrating the so-called interconnected receive module which consists of four monolithic chips - the low noise front-end amplifier (LNA), the five bit phase shifter (PS), the gain control amplifier (GC), and the RF to IF downconverter (RF/IF). Results on all four individual chips have been obtained and interconnection of the first three functions has been accomplished. Future work on this contract is aimed at a higher level of integration, i.e., integration of the first three functions (LNA + PS + GC) on a single GaAs chip. The report presents the status of this technology and projections of its future directions.

Keywords: ELECTRONICS AND ELECTRICAL ENGINEERING

Type: NASA-CR-180825 , NAS 1.26:180825

Format: application/pdf

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A Ka-band GaAs monolithic phase shifter (1983)

Contolatis, A. ; Chao, C. ; Geddes, J. J. ; [et al.]

In: Other Sources

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Publication Date: 2019-06-28

Description: The design and performance of a GaAs monolithic 180-degree one-bit switched line phase shifter test circuit for Ka-band operation is presented. A self-aligned gate (SAG) fabrication technique is also described that reduces resistive parasitics in the switching FET's. Over the 27.5-30 GHz band, typical measured differential insertion phase is within 10-20 deg of the ideal time delay characteristic. Over the same band, the insertion loss for the SAG phase shifter is about 2.5-3 dB per bit. The SAG fabrication technique holds promise in reducing phase shifter insertion loss to about 1.5 dB/bit for 30-GHz operation.

Keywords: ELECTRONICS AND ELECTRICAL ENGINEERING

Type: IEEE Transactions on Microwave Theory and Techniques (ISSN 0018-9480); MTT-31; 1077-108

Format: text

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30 GHz monolithic balanced mixers using an ion-implanted FET-compatible 3-inch GaAs wafer process technology (1986)

Sokolov, V. ; Chao, C. ; Contolatis, A. ; [et al.]

In: Other Sources

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Publication Date: 2019-06-28

Description: An all ion-implanted Schottky barrier mixer diode which has a cutoff frequency greater than 1000 GHz has been developed. This new device is planar and FET-compatible and employs a projection lithography 3-inch wafer process. A Ka-band monolithic balanced mixer based on this device has been designed, fabricated and tested. A conversion loss of 8 dB has been measured with a LO drive of 10 dBm at 30 GHz.

Keywords: ELECTRONICS AND ELECTRICAL ENGINEERING

Format: text

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5

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The 30-GHz monolithic receive module (1983)

Geddes, J. ; Sokolov, V. ; Bauhahn, P.

In: CASI

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Publication Date: 2019-07-13

Description: Key requirements for a 30 GHz GaAs monolithic receive module for spaceborne communication antenna feed array applications include an overall receive module noise figure of 5 dB, a 30 dB RF to IF gain with six levels of intermediate gain control, a five-bit phase shifter, and a maximum power consumption of 250 mW. The RF designs for each of the four submodules (low noise amplifier, some gain control, phase shifter, and RF to IF sub-module) are presented. Except for the phase shifter, high frequency, low noise FETs with sub-half micron gate lengths are employed in the submodules. For the gain control, a two stage dual gate FET amplifier is used. The phase shifter is of the passive switched line type and consists of 5-bits. It uses relatively large gate width FETs (with zero drain to source bias) as the switching elements. A 20 GHz local oscillator buffer amplifier, a FET compatible balanced mixer, and a 5-8 GHz IF amplifier constitute the RF/IF sub-module. Phase shifter fabrication using ion implantation and a self-aligned gate technique is described. Preliminary RF results obtained on such phase shifters are included.

Keywords: COMMUNICATIONS AND RADAR

Type: NASA-CR-168326 , NAS 1.26:168326 , AR-1

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6

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The 30-GHz monolithic receive module (1988)

Contolatis, T. ; Sokolov, V. ; Geddes, J. ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: The fourth year progress is described on a program to develop a 27.5 to 30 GHz GaAs monolithic receive module for spaceborne-communication antenna feed array applications, and to deliver submodules for experimental evaluation. Program goals include an overall receive module noise figure of 5 dB, a 30 dB RF to IF gain with six levels of intermediate gain control, a five bit phase shifter, and a maximum power consumption of 250 mW. Submicron gate length single and dual gate FETs are described and applied in the development of monolithic gain control amplifiers and low noise amplifiers. A two-stage monolithic gain control amplifier based on ion implanted dual gate MESFETs was designed and fabricated. The gain control amplifier has a gain of 12 dB at 29 GHz with a gain control range of over 13 dB. A two-stage monolithic low noise amplifier based on ion implanted MESFETs which provides 7 dB gain with 6.2 dB noise figure at 29 GHz was also developed. An interconnected receive module containing LNA, gain control, and phase shifter submodules was built using the LNA and gain control ICs as well as a monolithic phase shifter developed previously under this program. The design, fabrication, and evaluation of this interconnected receiver is presented. Progress in the development of an RF/IF submodule containing a unique ion implanted diode mixer diode and a broadband balanced mixer monolithic IC with on-chip IF amplifier and the initial design of circuits for the RF portion of a two submodule receiver are also discussed.

Keywords: COMMUNICATIONS AND RADAR

Type: NASA-CR-180849 , NAS 1.26:180849

Format: application/pdf

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