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InPi,SiGE MMIC and ADC/DAC in military/space application
milstar: http://www.youtube.com/watch?v=lWvr4mfP6A0&feature=related 14 awgusta 2010 yspeschno zapuschen AEHF s InPi AFAR (werojanto polnoj ,antenni na 20 ghz razmerom primerno do 1 metra diametrom ,na kazduju s h/2 do 8000 mmic,po publ dannim 10000) http://www.as.northropgrumman.com/products/aehf/assets/AEHF_datasheet_2010_.pdf AEHF maintains significant margin for enhancement (3K lbs in mass and 4KW in available power). ******************************************************************************* http://www.lockheedmartin.com/data/assets/ssc/aehf/C10010_AEHFFactsheet_V2(Final)June2010.pdf • CIP is a funded program to study the evolution of advanced missions for AEHF, including Communications On-The-Move (COTM). • CIP is an effort of the Air Force Space and Missile Center Advanced Concept Group. In Nov. 2001, the U.S. Air Force awarded Lockheed Martin Space Systems and Northrop Grumman Space Technology (Formerly TRW Space & Electronics) a $2.698 billion contract to begin the System Development and Demonstration (SDD) phase of the Advanced Extremely High Frequency (Advanced EHF) Program. The Advanced EHF Program is the next generation of global, highly secure, survivable communications system for Warfighters within all services of the Department of Defense. http://www.lockheedmartin.com/products/AdvancedExtremelyHighFrequencyEHF/index.html The AEHF system’s design provides data and voice networking and videoconferencing, along with sensor imagery. The capacity is 430 megabits a second per satellite on each of three spacecraft. Tactical communications are at 8 megabits per second *********************************************** and strategic communications at 19.2 kilobits per second. ************************************************** There is an order of magnitude improvement in system capacity over Milstar, with an increase of five times in data rate, servicing up to 6,000 terminals and 4,000 networks, the colonel assures. Each AEHF employs more than 50 communications channels via multiple, simultaneous downlinks. The system also uses massive numbers of application specific integrated circuits (ASICs), ************************************************************************** AEHF allows one phased array antenna to do the job of many reflectors, greatly improving warfighter communications access, the colonel notes. One of the new technologies developed for the AEHF payload, the uplink phased array antenna will receive signals from ground terminals. This new technology directs agile radio frequency beams electronically instead of by mechanically moving reflectors, Col. Harding says. “Phased arrays provide an agile ability to rapidly jump the beam around from user to user, where traditional gimbals must dedicate the beam to one user at a time.” Boewaya ystojshiwost* phase array/solid state protiw cassegr./twt xuze ************************************************************** http://www.afcea.org/signal/articles/templates/SIGNAL_Article_Template.asp?articleid=988&zoneid=4 Operating at 44 gigahertz, the space-based phased array antenna also uses indium phosphide (InP), an advanced semiconductor material, for some of the antenna’s more than 10,000 monolithic microwave integrated circuits. ******************************************************************************************* InP ensures excellent low noise, or clear signal, performance. With a more compact phased array, the AEHF system can process greater amounts of information. In the progression of extremely high frequency (EHF) satellites, the total Milstar I system throughput moved from 75 kilobits per second to 100 megabits per second with Milstar II and to 1 gigabit per second with the AEHF system’s extended data rate capability with three satellites, Col. Harding states. 2 antenni phase arrray na peredachu ,downlink 20 ghz i odna pomenschne na priem 44 ghz http://www.as.northropgrumman.com/products/aehf/assets/AEHF_datasheet_2010_.pdf Na risunke phasirowannie reschetki 2 * 6-ygolnix na 20 ghz downlink /transmit i rjadom pomensche 44 ghz uplink /reseive ######################################################## Starie dannie - http://www.deagel.com/news/AEHF-Demonstrates-Uplink-Phased-Array-Antenna-Technology_n000000247.aspx The AEHF uplink antenna will be the first operating at 44 GHz. In addition, it will utilize the new semiconductor material, Indium Phosphide (InP), for some of the antenna's more than 10,000 monolithic microwave integrated circuits. InP semiconductor provides low noise or clear signal performance. The first AEHF flight payload is scheduled for delivery in April 2006. Voprosi TWT ili GaAS ili InP S tochki zrenija boewoj ystojchiwosti w jadernoj wojne -TWT lutschee reschenie S tochki zrenija riska -toze GaAS bolee riskowannoe reschenie ,InP tem bolee (Net takogo naleta na orbite kak s TWT) ******************************************* Primary Function: Near-worldwide, secure, survivable satellite communications Primary Contractor: Lockheed Martin Space Systems Company Payload: Onboard signal processing, crossbanded EHF/SHF communications ranee bilo w Milstar Antennas: 2 SHF Downlink Phased Arrays(20 ghz), -ranee nebilo w milstar ,no bilo w sowetskom Potok C -Band (Elsov,Spurt FGUP,sistema swjazi Surgut) ne jasno 1.Aktivnaja ili passivnaja 2. TWT ili GaAS .Milstar - TWT .boewaja ystojchiwost* wische 2 Crosslinks, 2 Uplink/Downlink Nulling Antennas, -bilo w milstar disain ems priwodil http://www.emsdss.com/uploadedFiles/pdf/BFN.pdf http://www.emsdss.com/solutions/paperslist.aspx?id=199&coll_id=14 A major milestone came in 1976 when EMS built the first electronically steerable antenna flown in space for the Defense Satellite Communications System (DSCS) satellite, precursor to both Milstar and Advanced EHF, built to ensure secure communication transmissions among U.S. military and country leaders. Today, almost every major military satellite flying in space carries EMS hardware. http://www.ems-t.com/uploadedFiles/emst/Press_Room/Press_Releases/Corporate/2007/07-16-07_Pippin.pdf 1 Uplink EHF Phased Array, (44 ghz) te ze woprosi chto k dwonlink phase array 6 Uplink/Downlink Gimbaled Dish Antenna, 1 Each Uplink/downlink earth coverage horns Capability: Data rates from 75 bps to approximately 8 Mbps http://www.losangeles.af.mil/library/factsheets/factsheet.asp?id=5319
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milstar: 10 bit 2.2 gigasample SiGe ADC dlja SAR kosmicheskogo bazirowanija (nachalo 2000 godow) http://www.atmel.com/journal/documents/issue6/Pg43_48_CodePatch.pdf http://solidearth.jpl.nasa.gov/insar/documents/InSAR_Concept_Study%20Report_7-27-04c.pdf ISAR dlja NASA space based radar s ATMEL 2.2 gigasamples / 10 bit SiGE opsianie http://www.atmel.com/journal/documents/issue6/Pg43_48_CodePatch.pdf 4.1.2 Radar Hardware Electronics Development An internal technology assessment workshop was held in October, 2003. The purpose of this workshop was to assess past technology developments and identify common radar components suitable for additional technology investment by InSAR. This was accomplished by surveying past technology investments and new candidate technologies to understand adaptability to InSAR as well as other planned missions such as Aquarius, WSOA, Hydros and potentially UAV SAR. Based on the results of this workshop, the development of the following radar electronics prototypes was initiated to raise the TRL: 1) L-band RF Transceiver; 2) AD-9858 NCO-based Digital Chirp Generator; 3) Atmel TS8388 Analog-to-Digital Converter and 1:8 Demux; ######################################### 10 bit 2.2 gigasamples SiGE 4) Xilinx FPGA-based Block Floating Point Quantizer (BFPQ). In addition, the instrument architecture has been refined to utilize the new hardware technologies. Table 4-1. Radar Instrument Characteristics Item Value/Summary Sensor type Synthetic aperture radar Frequency and polarization L-band single-polarization (HH) Signal-to-noise ratio Noise equivalent sigma naught less than –24 dB Swath width Larger than 340 km (viewable) to obtain global access Bandwidth 80 MHz (maximum) and split spectrum capability to perform two subbands processing for ionospheric correction Instrument modes Stripmap (3 possible beams), High-Resolution and ScanSAR Antenna aperture 13.8 m x 2.5 m (with distributed T/R modules) Antenna incidence angle From 20-deg to 40-deg (electronic beam steering) Transmit power 3.5 KW Antenna structure Deployable Data acquisition duty cycle 10 min/orbit average (200 W average power per orbit) Radar electronics redundancy Full redundancy (with cross-strapping) of radar electronics for 5-year mission lifetime Instrument mass 600 kg including 30% contingency Instrument DC power 1800 W peak (during data take) including 30% contingency Instrument data rate 130 Mbps average High-Resolution Mode: The High-Resolution Mode is an 80 MHz mode that trades swath coverage for increased resolution (10 m). One of seven beams may be chosen in this mode; each with a swath width of ~40 km. Operation in this mode would be in lieu of the primary 35 m resolution Stripmap Mode and would be performed intermittently at the request of the Science Team when targets of interest requiring higher resolution are identified The current InSAR baseline eight-day sun-synchronous orbit at 760 km altitude yields a separation of ~340 km at the equator between adjacent nadir tracks, as shown in the following figure. In order to meet the requirement for complete global access the InSAR Payload System will be designed such that the accessible area (viewable swath) is greater than or equal to 340 km.
milstar: The 2.2Gbps MAX109 is fabricated with an advanced SiGE process http://www.maxim-ic.com/app-notes/index.mvp/id/810 * Ultra-High-Speed, 8-Bit, 2.2Gsps ADC * 2.8GHz Full-Power Analog Input Bandwidth * Excellent Signal-to-Noise Performance o 44.6dB SNR at fIN = 300MHz o 44dB SNR at fIN = 1600MHz * Superior Dynamic Range at High-IF o 61.7dBc SFDR at fIN = 300MHz o 50.3dBc SFDR at fIN = 1600MHz o -60dBc IM3 at fIN1 = 1590MHz and fIN2 = 1610MHz * 500mVP-P Differential Analog Inputs * 6.8W Typical Power Including the Demultiplexer * Adjustable Range for Offset, Full-Scale, and Sampling Instance * 50Ω Differential Analog Inputs * 1:4 Demultiplexed LVDS Outputs * Interfaces Directly to Common FPGAs with DDR and QDR Modes # ATE Systems # Digital Oscilloscopes # Digital RF/IF Signal Processing # Electronic Warfare (EW) Systems # High-Energy Physics Instrumentation # High-Speed Data-Acquisition Systems # Light Detection and Ranging (LIDAR) # Radar Warning Receivers (RWR) Control inputs are provided for interleaving additional MAX109 devices to increase the effective system-sampling rate. The MAX109 is offered in a 256-pin Super Ball-Grid Array (SBGA) package and is specified over the extended industrial temperature range (-40°C to +85°C). http://www.maxim-ic.com/datasheet/index.mvp/id/5391 RF/IF Sampling Supports High-Speed Interleaving http://www.maxim-ic.com/datasheet/index.mvp/id/5391 6.8W Typical Power Including the Demultiplexer http://datasheets.maxim-ic.com/en/ds/MAX109.pdf
milstar: yrowen 2009 goda 8 bit Sige na osnowanii processa 190 ghz https://tspace.library.utoronto.ca/handle/1807/17508 https://tspace.library.utoronto.ca/handle/1807/17508 pdf link raboti tam ze ... Titel: An 8-bit, 12.5GS/s Folding-interpolating Analog-to-digital Converter Autor(en): Ghetmiri, Shohreh Advisor: Salama, C.A.T. Department: Electrical and Computer Engineering Stichwörter: An 8-bit, 12.5GS/s Folding-Interpolating Analog-to-Digital Converter high speed ADC shoreh ghetmiri Shohreh Ghetmiri C.A.T Salama Folding interpolating ADC 8 bit SiGe ADC IHP ADC Issue Date: 10-Aug-2009 Zusammenfassung: The motivation behind this work is to target the demand for high-speed medium-resolution ADCs for satellite communication systems. An 8-bit, 12.5GS/s folding-interpolating ADC was designed in 0.25µm, 190GHz SiGe BiCMOS technology from IHP. The ADC consists of a THA, a reference resistor ladder, folding amplifiers, an interpolating resistor string, a comparator array, a digital encoder, a coarse quantizer and a bit synchronizer. Post-layout simulation results of the ADC verify that its performance meets all the required specifications. By comparison to other high-speed ADCs, implemented in SiGe technologies, the present design features the highest sampling rate for 8-bit resolution ADCs to date with a good FOM (12.9pJ/conversion). The THA and the comparator were implemented experimentally and characterized to verify their performance and to ascertain the possibility of implementing the complete ADC. The experimental results meet the expected specifications and indicate that both circuits are suitable for the implementation of the ADC. URI: http://hdl.handle.net/1807/17508 Appears in Collections: Master
milstar: High Speed ADCs for Satellite Broadband Communications Receivers High speed ADCs are key building blocks in the next generation of satellite communication receivers. A conventional receiver architecture is illustrated in Figure 1.1. The RF input from the antenna passes through a low noise amplifier (LNA) and is amplified to the required signal level. By using several mixing stages, the signal spectrum is down-converted to the IF band [1]. The down-converted signal is then processed through a medium resolution ADC to obtain digital codes which are used in further signal processing. The requirement for several down-conversion stages is predicated by the limited bandwidth of the ADC If wide-bandwidth ADCs are available, a single down-conversion can be used, as illustrated in Figure 1.2, thus improving the linearity of the receiver. Using such an approach, in a satellite communication system, with an RF 64QAM signal in the 10-30GHz range, one down-conversion results in an IF signal in the 1-3GHz range. In this case, the high-speed ADC must have an input bandwidth of 3GHz with a typical resolution of 8bits*. The sampling frequency of the ADC must be higher than the Nyquist rate to compensate for performance degradation near the Nyquist bandwidth. Thesis Objectives The objective of this work is to design an 8-bit, 12.5GS/s ADC for wideband satellite communication receivers. The selected technology for the implementation is the 0.25μm SiGe BiCMOS process from IHP**. Operating from a nominal supply voltage of 3.3V, the peak ft for a minimum geometry bipolar transistor in this technology is 190GHz. The target specifications for the proposed ADC are listed in Table 1.2. None of the previously reported ADC designs meet these specifications. The thesis is organized as follows. Chapter 2 presents a detailed discussion of the folding-interpolating ADC architecture. In addition, schematic designs, layouts and post layout simulations of the major building blocks of the ADC are presented. The simulation and characterization of the complete ADC in both schematic and post layout views are presented in **IHP tabl 3 15 watt raseiwaemaja moschn. ENOB -7.5 bit/3.125 ghz SNDR -45 db/3.125 ghz 12.5 gigasample /sec 3.3 volt pitanie The process chosen to implement the folding-interpolating ADC is a 0.25μm, 190 GHz SiGe BiCMOS technology from IHP (SG25H1). This technology provides high-speed npn SiGe HBTs, CMOS transistors, metal-insulator-metal (MIM) capacitors, poly-Si resistors, as well as 5 aluminum metal layers (metal1 to metal5) with tungsten local interconnect [7]. A key feature of the technology is the implementation of the entire HBT structure in a single active area with no shallow trench isolation between the active emitter and the collector contact region as shown in Figure 2.8 [7]. This reduces the collector to substrate capacitance and the collector resistance [8] resulting in high ft and fmax for the transistors.
milstar: Maxtek -postawschik top 30 Defense kompanij 8-bit ADC ,IBM SiGE 7HP BiCMOS 0.18 microna ,12.5 gigasample ,6.25 ghz SFDR - 50 dbc ,ENOB -6.6 bit in 0 -5 ghz http://www.maxtek.com/MaxtekDataConverterModules.pdf http://www.synopsys.com/Services/CapsuleModule/Maxtek_ss.pdf Using Synopsys Professional Services was the best choice for achieving our project’s high-performance objectives. Their FPGA design experience and prototyping expertise were key factors in our decision, and more importantly, in achieving our aggressive project objectives.”
milstar: DALLAS, Oct. 26 2009 industry's first 12-bit, 1-GSPS ADC ,775 $ za stuku w partijax po 100 http://newscenter.ti.com/Blogs/newsroom/archive/2009/10/26/texas-instruments-unveils-industry-s-first-12-bit-1-gsps-adc-with-buffered-input-simplifying-analog-front-end-design-in-wide-bandwidth-applications-250954.aspx Developed on TI's high-speed, proprietary BiCom3( )complementary bipolar SiGe technology, the monolithic ADS5400 is specified over the full industrial temperature range (-40 degrees C to 85 degrees C). The BiCom3 technology's silicon-on-insulator (SOI) process makes it well suited for high-temperature and high-radiation environments. The ADS5400 offers an unmatched signal-to-noise ratio (SNR) of 59 dBFS and 75 dBc spurious-free dynamic range (SFDR) in first Nyquist, and 58 dBFS SNR and 70 dBc SFDR performance for intermediate frequencies (IFs) beyond 1000 MHz. Fully buffered, 12-bit, 1-GSPS ADC with 2.1 GHz input bandwidth, for wideband signals in oversampling and undersampling applications with 200 MHz or greater signal bandwidth Customers can speed time-to-market with compatible TI devices: THS9000 and THS9001 amplifiers to support input frequencies up to 500 MHz; the CDCE72010 high-performance, low phase noise, and low skew clock; the DAC5682Z dual, 16-bit, 1 GSPS DAC; the TPS727xx and TPS717xx low dropout regulators; and the TMS320C6474 and TMS320C6457 DSPs. http://focus.ti.com/lit/ds/symlink/ads5400.pdf 3 stage pipeline SFDR Fi 850 mgz -71 db 1200 mgz -66 db 1700 mgz -56 db SINAD 125 mgz -58.5 db 1700 mgz -54.2 db ENOB used SINAD 850 mgz -9.3 db T.e. verojatno mozno ispolzowat w AFAR X-Band (8-10 ghz) s odnoj promezutochnoj 1.2 ghz i polosoj signala 1000 mgz (700-1700 mgz)- razreschajuschaja sposobnost -250 mm "Customers can use the ADS5400's ground-breaking combination of resolution, sample rate and bandwidth to significantly enhance applications in defense by improving radar and signal intelligence (SIGINT) capabilities, and can double the capture bandwidth of signals with 12-bit resolution in test and measurement," said Art George, senior vice president of TI's High-Performance Analog business unit. ..... W broschure po Global Hawk RQ-4 block 20 http://www.as.northropgrumman.com/products/ghrq4b/assets/GH_Brochure.pdf rasreschajuschaj sposbmsot Radara danna - 1/ 0.3 metra na linke Sandia Lab snimki s razreschajuschej sposonostju 10 santimetrow #################### Mozete posmotret http://www.sandia.gov/RADAR/images/ka_band_portfolio.pdf Rjad video s raschreschajuschej sposobnostju 30 santimetrow i 1 metr tam ze http://www.sandia.gov/RADAR/movies.html ################################### Automatic Target Recognition http://www.sandia.gov/atr/
milstar: Built with TI’s BiCom3™ SiGe process http://www.ti.com/ww/en/analog/ads5400/index.shtml?DCMP=hpa_dc_ads5400&HQS=Other+PR+ads5400-pr ADS5485 ADS5483 ADS5481 ADS5463 ADS5474 ADS54RF63 ADS5400 12,14 i 16 bit SiGE ADC ####################### Device ADS5400 Resolution (Bits) 12 Speed (MSPS) 1000 SNR (dBFS) 59 SFDR (dBc) 78 SINAD (dBc) 57.8 ################# Device ADS5485 ADS5483 ADS5481 Resolution (Bits) 16 16 16 Speed (MSPS) 200 135 80 SNR (dBFS) 75 79 80.6 SFDR (dBc) 87 97 98 SINAD (dBc) 73.7 77.8 79.5 chart
milstar: SiGE in X-band radar ... T/R module ,phase shifter http://cmoset.com/uploads/4a.9.09.pdf http://www.ieee-sem.org/ChapterIV/090513_JohnCressler_Slides.pdf
milstar: 8bit ,10 gigasamples 12 watt juli 2010 , folding and interpolating http://www.electronicsweekly.com/Articles/2010/07/02/48957/hands-on-with-rohde.htm 07 2010 A single core 8bit 10Gsample/s SiGe ADC digitises incoming signals on each channel. It had to be single-core, because for all their advantages, multi-core designs add a small amount of jitter - and the firm as almost paranoid about jitter and noise. The in-house design achieves 7.2 effective bits. "The target was to build the lowest noise scope on the market," said Wolf. "We have seen scopes with only five effective bits." Flash conversion, using 255 comparators in the converter, was rejected on the grounds of power consumption. ------------------------------------- "The architecture is folding and interpolating, ------------------------------------------------- and the converter dissipates 12W," Wolf told Electronics Weekly.
milstar: http://www.analog.com/static/imported-files/data_sheets/AD9467.pdf “This is a breakthrough device. It’s pushing the state of art,” Jon Hall, ADI’s strategic marketing and applications manager for high-speed converters, said in an interview. The performance and power gains came thanks to a process shift rather than a process shrink. --------------------------------------------------------- The device is fabricated on .18 silicon germanium BiCMOS, ######################################################### where similar earlier devices were in CMOS. http://www.eetimes.com/electronics-products/electronic-product-reviews/analog-products/4208854/Analog-Devices-offers-16-bit-ADC-at-250-MSPS Togda mozno predpolozit wozmoznost sodanija 18 bit 100 msps s rasseiwaemoj moschnostju 10 watt i SFDR 107 db na Fin 70 mgz(standartnaja 2 pch w satcom) ################################ Product Review Analog Devices offers 16-bit ADC at 250 MSPS Brian Fuller 9/27/2010 6:57 PM EDT Comment Jon.Hall 10/21/2010 5:43 PM EDT The latency of the AD9467 is determined by the actual pipeline architecture. The ... GREAT-Terry 10/11/2010 8:15 AM EDT It is said to be a pipeline ADC. From the datasheet, the latency is 16 cycles. ... More Comments > Claiming a breakthrough in speed for the high-performance segment, Analog Devices today announced the AD9647 16-bit A/D converter operating at 250 MSPS (mega samples per second). The device, intended to drive the company’s converter presence broader and deeper into military, industrial and wireless applications, is said to have a sampling rate that is 25 percent faster than competitive devices. It uses 35 percent less power, at 1.32W total power dissipation including drivers, than competing devices, the company claimed. Key features: * 1.8 V and 3.3 V supply operation * 16-bit resolution with high signal bandwidths up to 300 MHz * On-chip IF (intermediate frequency) sampling circuit and buffered analog inputs * High dynamic range over broad signal bandwidth enables software-defined radios for use with multiple standards, such as LTE/W-CDMA, MC-GSM (class 1) and CDMA. * 75.5 dBFS SNR to 170 MHz at 250 MSPS @ 2.5 V p-p FS * 74 dBFS SNR to 170 MHz at 250 MSPS @ 2.0 V p-p FS * 90 dBFS SFDR to 300 MHz at 250 MSPS (@ −1 dBFS) at 2.5 V p-p FS * 95 dBFS SFDR to 170 MHz at 250 MSPS (@ −1 dBFS) at 2.0 V p-p FS * 100 dBFS SFDR at 100 MHz at 160 MSPS (@ −1 dBFS) * 60 fs rms Jitter “This is a breakthrough device. It’s pushing the state of art,” Jon Hall, ADI’s strategic marketing and applications manager for high-speed converters, said in an interview. The performance and power gains came thanks to a process shift rather than a process shrink. The device is fabricated on .18 silicon germanium BiCMOS, where similar earlier devices were in CMOS. http://www.eetimes.com/electronics-products/electronic-product-reviews/analog-products/4208854/Analog-Devices-offers-16-bit-ADC-at-250-MSPS --
milstar: http://www.sige.com/products/gps/details.html
milstar: http://see.conference-services.net/resources/253/1452/pdf/RADAR2009_0293.pdf 3 GS/s S-Band 10 Bit ADC and 12 Bit DAC on SiGeC Technology
milstar: В таблице 2 приведены основные виды электровакуумных СВЧ приборов и устройств, имеющие мировой и российский приоритет, технические и технологические решения которых защищены патентами Российской Федерации. По совокупности своих технических и эксплуатационных характеристик эти приборы являются лучшими в своих классах и определяют мировой технический уровень. В таблице приведены области применения этих СВЧ приборов, лидирующие предприятия-разработчики и изготовители, а также представлены применяемые для этих же целей приборы за рубежом и их изготовители. http://www.hse.ru/data/2013/02/12/1308493137/СПИ%20ТП%20СВЧ%20технологии%2025%2012%202012.pdf СТРАТЕГИЧЕСКАЯ ПРОГРАММА ИССЛЕДОВАНИЙ технологической платформы «СВЧ технологии» Утверждена 17 декабря 2012 года на заседании Наблюдательного совета технологической платформы «СВЧ технологии» под председательством А.С. Якунина Директора Департамента радиоэлектронной промышленности Министерства промышленности и торговли Российской Федерации Основными потребителями СВЧ приборов и устройств являются предприятия ОПК радиоэлектронного профиля, разрабатывающие и серийно выпускающие радиоэлектронную аппаратуру прежде всего военного и, наряду с ней, аппаратуру двойного и (или) гражданского назначения. Наиболее крупными из них, формирующими рынок радиоэлектронной военной продукции являются предприятия, входящие в ОАО «Концерн ПВО «Алмаз-Антей» (ОАО ГСКБ «Алмаз-Антей» (Москва), ОАО «НИИ приборостроения им. В.В.Тихомирова» (Жуковский Московской обл.), ФГУП «ГРПЗ» (Рязань), ОАО «НИИ «Стрела» (Тула), ОАО МНИИ «Альтаир», ОАО «ВНИИРТ» (Москва), ОАО «ННИИРТ» (Нижний Новгород), а также ОАО «КБП» (Тула), ОАО «КБМ» (Коломна Московской обл.), ОАО «ЦКБА» (Омск), ФГУП «КНИРТИ» (Жуков Калужской обл.), ОАО «Корпорация «Тактической ракетной вооружение», ОАО ГосМКБ «Вымпел», ОАО ГосМКБ «Факел», ОАО «Российские космические системы», ФГУП «ЦНИИ «Комета» (Москва) и др. Разрабатываемые и выпускаемые ими системы радиоэлектронного вооружения на период до 2020 года будут в основном определять загруженность предприятий ОПК, в том числе и СВЧ подотрасли. Только по номенклатуре ФГУП «НПП «Исток» (Фрязино Московской обл.), разрабатывающему и серийно выпускающему СВЧ приборы и устройства для более 100 образцов современного и перспективного вооружения, объемы производства к 2017-2018 гг. планируется увеличить: по кристальному производству транзисторов и МИС СВЧ в 26 раз; по производству модулей СВЧ, в том числе для АФАР в 12 раз; по электровакуумным СВЧ приборам и КИ СВЧ в 2,3 раза; по радиоэлектронным устройствам в 4 раза.
milstar: Target Discrimination Target discrimination is a critical capability for the ASM seeker, especially in the presence of jamming and other EA (Electronic Attack). For this analysis, it is only indicated that the coherent seeker presents more information at, perhaps higher resolution, to the postprocessor for discrimination purposes https://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.928.3912&rep=rep1&type=pdf
milstar: BLOOMINGTON, MN, October 21, 2019 – SkyWater Technology, the innovator’s trusted partner for a competitive edge, announced the US Department of Defense (DOD) is planning to invest up to $170 million for a multi-phase project to enhance microelectronics capabilities for the DoD and the Strategic Radiation Hardened (Rad-Hard) market. SkyWater will be expanding its Trusted Foundry facility to add clean room area and supporting infrastructure to enable this and other complementary technologies. The initial phase is funded at $80 million and SkyWater will leverage this investment to develop a new 90 nm rad-hard electronics production capability to complement its existing 90 nm rad-tolerant offering https://www.skywatertechnology.com/press-releases/us-department-of-defense-to-invest-up-to-170m-at-skywater-for-rad-hard-technology/ The Most Advanced U.S. Foundry for Rad-Hard by Process Technologies SkyWater’s 90 nm Strategic Rad-Hard by Process technologies will set a new standard for hardened microelectronics. Read more below about the developing technology. https://www.skywatertechnology.com/technology/rad-hard-microelectronics/ https://www.skywatertechnology.com/rad-hard-eap/
milstar: https://www.baesystems.com/en-us/product/radiation-hardened-application-specific-integrated-circuits--asics-
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