ELVEES Multicore
Today, ELVEES Multicore has captured the attention of millions of people around the world. Since its discovery, ELVEES Multicore has been the subject of debate, research and fascination. Experts and hobbyists alike have spent countless hours unraveling the mysteries surrounding ELVEES Multicore, exploring its origins, impact, and possible implications for the future. In this article, we will delve into the intriguing world of ELVEES Multicore, examining its importance and relevance in different areas of daily life. Join us on this journey to discover everything behind ELVEES Multicore and how it has influenced our society.
| General information | |
|---|---|
| Launched | 2004 |
| Designed by | ELVEES |
| Performance | |
| Max. CPU clock rate | 80 MHz to 1.5 GHz |
| Architecture and classification | |
| Technology node | 250 nm to 16 nm |
| Instruction set | CPU MIPS32 + DSP ELcore |
| Physical specifications | |
| Cores |
|
Multicore (Russian: МУЛЬТИКОР) is a series of 32-bit microprocessors with embedded DSP cores developed by ELVEES, Russia.[1] The microprocessor is a MIPS32 core (called RISCore32 by ELVEES; optionally with an FPU) or an ARM Cortex-A9 core. Some of the processors in the series are radiation hardened (rad-hard) for space applications.
Overview
| Device | Microprocessor core | DSP core | Production start (year) | Process (nm) | Clock rate (MHz) | Remarks |
|---|---|---|---|---|---|---|
| 1892VM1T | RISCore32 | 1x ELcore | ? | ? | ? | [2] |
| 1892VM1Ya | RISCore32 | 1x ELcore | ? | ? | ? | [2][3] |
| 1892VM2Ya | RISCore32 | 1x ELcore-24 | 2005 | 250 | 80 | [2][3][4][5] |
| 1892VM3T | RISCore32 | 1x ELcore-14 | 2005 | 250 | 80 | [2][3][4] |
| 1892VM4Ya | RISCore32 | 2x ELcore-26 | 2006 | 250 | 100 | [2][3][4][6] |
| 1892VM5Ya | RISCore32 | 2x ELcore-26 | 2006 | 250 | 100 | [2][3][4][6] |
| 1892VM5BYa | RISCore32 | 2x ELcore-26 | ? | ? | 90 | [3] |
| 1892VM7Ya | RISCore32 + FPU | 4x ELcore-28 | 2009 | 130 | 200 | [4][5][7] |
| 1892VM8Ya | RISCore32 + FPU | 1x ELcore-26 | 2010 | 250 | 80 | rad-hard[2][3][5][8][9] |
| 1892VM10Ya | RISCore32 + FPU | 2x ELcore-30 | 2012 | 130 | 250 | [3][7] |
| 1892VM11Ya | RISCore32 + FPU | 2x ELcore-30 | 2011 | 65 | 500 | [10] |
| 1892VM12AT | RISCore32 + FPU | — | 2013 | 180 | 100 | rad-hard[5][7][8][9] |
| 1892VM14Ya | 2x ARM Cortex-A9 + GPU Mali-300 | 2x ELcore-30M | 2014 | 40 | 816 | [7][8][9] |
| 1892VM15AF | RISCore32 + FPU | 2x ELcore-30M | 2014 | 180 | 120 | rad-hard[5][7][8][9] |
| 1892VM16T | RISCore32 + FPU | 1x ELcore | 2014 | 180 | 110 | rad-hard[2][8][11][12] |
| 1892VM17F | RISCore32 + FPU | 1x ELcore | 2014 | 180 | 110 | rad-hard[2][8][11][12] |
| 1892VM18F | RISCore32 + FPU | 2x ELcore | 2015 | 180 | 110 | rad-hard[2][8][11][12] |
| 1892VM196 | RISCore32 + FPU | — | 2018 | 180 | 120 | rad-hard[7][8] |
| 1892VM206 | RISCore32 + FPU | 2x ELcore-30M | 2018 | 180 | 120 | rad-hard[7][8] |
| 1892VM218 | ? | ? | ? | ? | ? | |
| 1892VM226 | ? | ? | 2020 ? | ? | ? | rad-hard[9] |
| 1892VM236 | ? | ? | 2019 | 90 | ? | rad-hard[8][9] |
| 1892VM248 | 8x MIPS64 + PowerVR GPU | 16x ELcore-50 | 2020 ? | 16 | 1500 | [9] |
| 1892VM258 | ? | ? | ? | ? | ? | |
| 1892VM268 | ARM Cortex-M33 | ? | 2021 ? | ? | ? | [13] |
| 1892VA018 | 4x ARM Cortex-A53 + PowerVR GPU | 2x ELcore-50 | 2020 ? | ? | 1200 | [9] |
| 1892VK016 | 2x RISCore32 | — | 2019 | 180 | 100 | rad-hard[5][7][9] |
| 1892VK024 | RISCore32 + FPU | 2x ELcore | 2020 ? | 180 | ? | rad-hard[5][9] |
| 1892KP1Ya | RISCore32 | — | 2010 | ? | 100 | rad-hard[2][3][5][7][9] |
| 1892KhD2Ya | RISCore32 | — | 2007 | ? | ? | rad-hard[2][3][4][5][9] |
Details
1892VM1Ya
1892VM2Ya
- Russian: 1892ВМ2Я (MC-24)
- 2 cores: RISCore32 + ELcore-24 (DSP-core with SIMD architecture)
- manufactured in a 250 nm CMOS process
- 18 million transistors
- HSBGA292 package
1892VM3T
- Russian: 1892ВМ3Т (MC-12)
- 2 cores: RISCore32 + ELcore-14 (DSP-core with SISD architecture)
- manufactured in a 250 nm CMOS process
- 18 million transistors
- PQFP240 package
1892VM4Ya
- Russian: 1892ВМ4Я (MC-0226G, МЦОС)
- 3 cores: RISCore32 + 2x ELcore-26 (DSP-core with MIMD architecture)
- manufactured in a foundry outside Russia in a 250 nm CMOS process
- 26 million transistors
- HSBGA416 package
- includes 2 PCI controllers
1892VM5Ya
- Russian: 1892ВМ5Я (МС-0226, ЦПОС-02)
- 3 cores: RISCore32 + 2x ELcore-26 (DSP-core with MIMD architecture)
- manufactured in a foundry outside Russia in a 250 nm CMOS process
- 26 million transistors
- HSBGA416 package
- includes 1 PCI controller
1892VM7Ya
- Russian: 1892ВМ7Я (МС-0428)
- 130 nm CMOS process, 81 million transistors
- HSBGA765 package
- includes 2 SpaceWire ports
1892VM8Ya
- Russian: 1892ВМ8Я (MC-24R)
- manufactured by X-Fab Malaysia in a 250 nm CMOS process and later by TSMC in a 40 nm CMOS process (with the clock speed increased to 100 MHz)
- HSBGA416 package
- includes 2 SpaceWire ports; supports ECC memory
1892VM10Ya
- Russian: 1892ВМ10Я (NVCom-02T)
- manufactured in a foundry outside Russia in a 130 nm CMOS process
- does not contain any IP blocks from outside Russia[14]
- 50 million transistors
- HSBGA400 package
- includes 24-channel correlator for GPS / GLONASS
1892VM11Ya
- Russian: 1892ВМ11Я (NVCom-02)
- manufactured by Angstrem in a 65 nm CMOS process
- BGA586 package
- includes 24-channel correlator for GPS and GLONASS signals
1892VM12AT
- Russian: 1892ВМ12АТ (MCT-03P)
- manufactured in Zelenograd in a 180 nm CMOS process
- does not contain any IP blocks from outside Russia[14]
- CQFP240 package
- includes 2 SpaceWire ports; supports ECC memory
- radiation tolerance to not less than 300 kRad, working temperature from -60 to 85 °C
1892VM14Ya
- Russian: 1892ВМ14Я (MCom-02)
- manufactured by TSMC in a 40 nm CMOS process
- HFCBGA 1296 package
- includes 2 SpaceWire ports; hardware accelerators for H.264 and JPEG encoding; correlator for GPS and GLONASS signals
1892VM15AF
- Russian: 1892ВМ15АФ (MC-30SF6)
- manufactured in Zelenograd in a 180 nm CMOS process
- does not contain any IP blocks from outside Russia[14]
- CPGA720 package
- includes 2 SpaceWire ports; supports ECC memory; hardware accelerators for FFT and JPEG encoding
- power consumption 5 W
- triple redundancy for registers; radiation tolerance to not less than 300 kRad, working temperature from -60 to 85 °C
1892VM16T
- Russian: 1892ВМ16Т
- manufactured by Mikron Group in a 180 nm CMOS process
- CQFP240 package
- working temperature from -60 to 85 °C
1892VM17F
- Russian: 1892ВМ17Ф
- manufactured by Mikron Group in a 180 nm CMOS process
- CPGA416 package
- working temperature from -60 to 85 °C
1892VM18F
- Russian: 1892ВМ18Ф
- manufactured by Mikron Group in a 180 nm CMOS process
- CPGA720 package
- working temperature from -60 to 85 °C
1892VM196
- Russian: 1892ВМ196
- manufactured in Zelenograd in a 180 nm process
- does not contain any IP blocks from outside Russia
- CPGA416 package
- includes SpaceWire, ARINC 429, SPI, and CAN interfaces as well as a 12-bit, 100 kHz ADC
1892VM206
- Russian: 1892ВМ206
- manufactured in Zelenograd in a 180 nm process
- does not contain any IP blocks from outside Russia
- CPGA720 package
- includes SpaceWire, SpaceFibre, ARINC 429, AFDX, MIL-STD-1553, and CAN interfaces
1892VM226
1892VM236
- Russian: 1892ВМ236
- manufactured in Zelenograd in a 90 nm process
- includes SpaceWire interface
1892VM248
- Russian: 1892ВМ248 (RoboDeus)
- manufactured by TSMC in a 16 nm process
- intended for data centers and robotic systems
- MIPI CSI and DSI interfaces (4K / 60fps), hardware accelerators for H.264 and HEVC
- includes 10 Gigabit Ethernet, USB 3.1, HDMI, PCIe, and SATA interfaces
1892VA018
- Russian: 1892ВА018 (Scythian)
- intended for smart cameras, robotic systems, industrial automation
- MIPI CSI and DSI interfaces (4K / 60fps), hardware accelerators for H.264 and HEVC
- GNSS signal processor
- hardware accelerators for software-defined radios (FFT, Viterbi)
- includes Gigabit Ethernet and USB 3.0 interfaces
1892VK016
- Russian: 1892ВК016 (MCT-04R)
- manufactured in Russia in a 180 nm CMOS process
- CPGA720 package
- intended for SSD controllers; includes SpaceWire and SpaceFibre interfaces; ECC for internal and external memory
- radiation tolerance to not less than 200 kRad, working temperature from -60 to 85 °C
1892VK024
- Russian: 1892ВК024 (MCT-07R)
- manufactured in a 180 nm CMOS process
- includes SpaceFibre, MIL-STD-1553, and I²C interfaces as well as an 8-channel, 12-bit 200 kHz ADC
1892KP1Ya
- Russian: 1892КП1Я (MCK-022)
- manufactured in a CMOS process
- HSBGA-416 package
- includes 16-port SpaceWire router
- working temperature from -60 to 85 °C
1892KhD2Ya
- Russian: 1892ХД2Я (MCK-01)
- manufactured in a CMOS process
- HSBGA-416 package
- includes 16-port SpaceWire router
See also
References
- ^ Solokhina, Tatiana (23 June 2010). "Next Generation DSP Multi-Core Processor with SpaceWire Links as the Development of the 'MCFlight' Chipset For the On-Board Payload Data Processing Applications" (PDF). International Spacewire Conference 2010. St. Petersburg: Space Technology Centre, University of Dundee. pp. 313–318. Retrieved 12 January 2017.
- ^ a b c d e f g h i j k l "Изделия отечественного производства" [Domestic products] (in Russian). Moscow: AO "ENPO SPELS". Retrieved 1 September 2016.
- ^ a b c d e f g h i j "СЕРИЯ 1892" [1892 series] (in Russian). Promelektronika-VPK. Archived from the original on 1 March 2017. Retrieved 25 October 2017.
- ^ a b c d e f "КАТАЛОГ 2008" [Catalog 2008] (PDF) (in Russian). Elvees Multicore. Archived from the original (PDF) on 21 May 2009. Retrieved 4 March 2019.
- ^ a b c d e f g h i "eidOS" (in Russian). MiT. Retrieved 2021-03-09.
- ^ a b "Новые трехпроцессорные DSP-контроллеры "Мультикор"" [New 3-core DSP controllers "Multicore"] (in Russian). Elvees Multicore. 20 March 2006. Retrieved 12 January 2017.
- ^ a b c d e f g h i "КАТАЛОГ 2018" [Catalog 2018] (PDF) (in Russian). Elvees Multicore. Retrieved 4 March 2019.
- ^ a b c d e f g h i j Piskarev, M.S. (25 April 2018). "Процессоры "Мультикор": от оборудования КА до систем искусственного интеллекта" ["Multicore" processors: from spacecraft equipment to artificial intelligence systems] (PDF) (in Russian). Retrieved 26 November 2018.
- ^ a b c d e f g h i j k l Sergey Naumov (2020). АО НПЦ "ЭЛВИС" - Презентация компании [AO NPC "ELVEES" - Company presentation] (PDF). MES (in Russian). Moscow. Retrieved 2021-03-04.
- ^ "Цифровой сигнальный процессор 1892ВМ11Я (NVCOM-02)" [Digital signal processor 1892VM11Ya (NVCOM-02)] (in Russian). TechnoUnity. Retrieved 13 January 2017.
- ^ a b c "Серии Предприятия НИИМЭ и Микрон" [Series from the company NIIME and Micron] (in Russian). Optochip. Retrieved 8 February 2018.
- ^ a b c "Микросхемы ПАО Микрон 2020" [Integrated Circuits PAO Mikron 2020] (PDF) (in Russian). Mikron. Retrieved 16 February 2021.
- ^ Sergey Gruzdyev (2021). Aladdin LiveOffice (PDF). TB Forum (in Russian). p. 12. Retrieved 2021-03-05.
- ^ a b c "Российские микросхемы 1 и 2 уровня" [Russian integrated circuits of the first and second level] (in Russian). Elvees Multicore. 23 January 2018. Retrieved 8 February 2018.
External links
- Official site of ELVEES Multicore (In Russian)