List of Xilinx FPGAs

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This article contains general information about field-programmable gate array (FPGA) devices from Xilinx, based on official specifications.

Terminology

The fields in the table listed below describe the following:

  • Model – The marketing name for the device, assigned by Xilinx.
  • Launch – Date when the product was announced.
  • Sub-models – Some FPGA models have multiple sub-models.
  • Flip-Flops (K) – The number of flip-flops embedded within the FPGA fabric.
  • LUTs (K) – The number of lookup tables embedded within the FPGA fabric.
  • DSP Slices – The number of digital signal processor slices embedded within the FPGA fabric.
  • Peak DSP Performance (GMAC/s) – The maximum number of multiply-accumulate operations per second that can be performed by the digital signal processors that are embedded within the FPGA fabric. This is a theoretical best-case number.
  • PCIe – Bus by which the device is attached to an external system.
  • Max Distributed RAM (Mb) – Random Access Memory within the LUTs.[1]
  • Total Block RAM (Mb) – On-chip RAM that is not integrated within the LUTs.
  • UltraRAM (Mb) – An additional block of RAM that was introduced with the Zynq UltraScale+ FPGA line. UltraRAM can be powered down for extended periods of time.[2]

Model naming

The model name of most devices has some indication of its size, but the exact scheme used has varied over time:

  • The first Xilinx device, the XC2064, is named after the 64 CLBs it contains
  • After that, Xilinx started including a rough approximation of device capacity in equivalent gate count (which is measured by synthesizing a large benchmark design corpus to both a standard gate library and to a given FPGA device, then deriving an approximate conversion factor from that):
    • XC2018 and all XC3000 devices use the gate count divided by 100 (ie. XC3020 is considered a rough equivalent of 2000 gates)[3]
    • XC4000, XC5200, XC6200, Spartan, Spartan-II, Spartan-3 (all kinds), Virtex, and Virtex-II (except for Virtex-II Pro) devices use the gate count divided by 1000 (ie. XC4003 is considered roughly equivalent to 3000 gates, XC3S5000 is considered roughly equivalent to 5 million gates). However, the device families differ in whether they use the low bound, average, or high bound of the conversion factor for the model name (eg. XC4003 uses the average of the estimated 2000-5000 gate range listed in the datasheet, while the functionally identical XCS05 uses the high bound of this range).
  • Virtex-II Pro and Virtex-4 devices instead started using an "equivalent logic cells" metric divided by 1000 (XC4VLX60 is considered to be an equivalent of 60000 logic cells). The logic cell is, nominally, a simple 4-input LUT paired with a flip-flop. The logic count is obtained by multiplying the LUT count of the device by an arbitrary effectiveness factor of 1.125 to account for the extra capacity of the hard CLB logic compared to a bare LUT.[4]
  • Virtex-5/6, Spartan-6, and 7 Series (not including Zynq-7000) continue using the same metric, but the effectiveness factor has been updated to 1.6, because of the upgrade from 4-input LUTs to 6-input LUTs.
  • UltraScale devices initially used the same "equivalent logic cells" metric, but divided by 10000 for the model name (ie. XCVU440 is considered to be equivalent to 4400000 logic cells), and with the effectiveness factor updated to 1.75 because of CLB upgrades. However, for marketing reasons, later versions of UltraScale data sheets instead started measuring device capacity in a new metric called "system logic cells", using an inflated conversion factor of 2.1875. This makes the model names seemingly unrelated to any device capacity measurements listed in the current data sheets.[5]
  • Zynq-7000, UltraScale+, and Versal devices abandon the idea of directly embedding logic capacity in the model name, assigning the names more or less arbitrarily.

Series overview

Generation Family Launch Process Internal operating voltage Notes
XC2000 XC2000 1985 2000nm[6] 5V The original FPGA family. This and a few following generations were originally called LCA (Logic Cell Array) devices, but later FPGA gradually became the preferred term.
XC2000L 1993[7] 3.3V Low voltage version of XC2000
XC3000 XC3000 1988 1200nm[6] 5V Improved logic cell, adds intra-FPGA tri-state bus support
XC3000A 1993 800nm[3] XC3000 with more functionality
XC3000L 1993 3.3V Low voltage version of XC3000A
XC3100 1992 800nm[8] 5V Faster version of XC3000
XC3100A 1994[9] 500nm Faster version of XC3000A
XC3100L 1995[10] 3.3V Faster version of XC3000L
XC4000 XC4000 1991 5V Improved logic cell, distributed RAM support, features carry chains and JTAG support
XC4000A 1991 5V XC4000 with fewer routing resources, small chips
XC4000D 1994[11] 5V Same as XC4000, but with non-functional RAM
XC4000H 1993 5V XC4000 with more, but less functional, IO cells (for higher pin count)
XC4000E 1995[12] 500nm[13] 5V XC4000 upgrade with more functionality
XC4000L 1995[10] 3.3V Low voltage version of XC4000E
XC4000EX 1996[14] 500nm 5V XC4000E upgrade with more routing resources, for larger devices
XC4000XL 1997 350nm[15] 3.3V Low voltage version of XC4000EX
XC4000XLA 1998[16] 350nm,[16] 250nm[15] 3.3V XC4000XL upgrade with more functionality
XC4000XV 1998 250nm[15] 2.5V XC4000XLA variant with more routing resources (for large chips)
Spartan 1998 500nm, 350nm[17] 5V Functionally identical to XC4000E, rebranded as low-end part
Spartan XL 1998[16] 350nm,[16] 250nm[17] 3.3V Spartan upgrade with more functionality
XC5200 XC5200 1994 600nm 5V A low end FPGA family with bare bones logic cells
XC5200L 500nm 3.3V Low voltage version of XC5200
XC6200 1995[12] 650nm 5V An unusual FPGA based on simple logic cells (not LUTs), meant to be used alongside a CPU and optimized for on-the-fly reconfiguration. The only FPGA to have a fully documented configuration format by Xilinx.
XC8100 1995[12] 5V or 3.3V A very unusual sea-of-gates FPGA, using one-time-programmable antifuse storage for the configuration (instead of RAM). Quickly discontinued in 1996.[18]
Virtex Virtex 1998[19] 220nm[13] 2.5V Improved LUT4-based logic cell, first Xilinx FPGA family to feature DLLs and block RAM
Spartan-II 2000 Identical to Virtex, marketed as low-end part
Virtex E 1999 180nm 1.8V Virtex upgrade with more block RAM, more DLLs, and improved IO cells (with differential IO support)
Virtex EM 2000 Like Virtex E, but with more block RAM
Spartan-IIE 2001[20] Identical to Virtex E, but with some blocks disabled
Virtex-II Virtex-II 2001 150nm 1.5V First Xilinx FPGA family to feature partial reconfiguration and hard multipliers, has DDR input/output support, DLLs have been replaced by much more functional DCMs
Virtex-II Pro 2002 130nm[21] 1.2V Virtex-II upgrade featuring first-generation multi-gigabit transceivers (3.125 Gbit/s, marketed as RocketIO™) and embedded PPC405 cores
Virtex-II Pro X 2003[22] Virtex-II Pro with multi-gigabit transceiver upgrade (RocketIO X, 6.25 Gbit/s)
Spartan-3 Spartan-3 2003 90nm[17] 1.2V A low-end, simplified version of Virtex-II
Spartan-3E 2004[23] Spartan-3 upgrade with improved hard multipliers and DCMs, but fewer IO cells
Spartan-3A 2006 Spartan-3E upgrade with improved block RAM (featuring byte enables) and IO cells
Spartan-3AN 2007 Spartan-3A version with integrated SPI flash (as a separate die within the same package), requiring no external bitstream storage
Spartan-3A DSP Spartan-3A upgrade with new DSP cells (based on Virtex-5 but simplified) replacing the simplistic hard multipliers
Virtex-4 2004 90nm 1.2V Introduced DSP cells replacing the simple hard multipliers, added simple serdes functionality to all IO cells, improved partial reconfiguration support
Virtex-4 LX The base "logic optimized" version
Virtex-4 SX DSP-optimized version of Virtex-4: identical functionality to LX, but with much higher DSP-to-logic ratio
Virtex-4 FX Virtex-4 with embedded hard PPC405 cores, Ethernet MAC blocks, and multi-gigabit transceivers (6.5 Gbit/s)
Virtex-5 2006 65nm 1.0V Introduced new LUT6-based logic cells, new block RAM cells (36kbit, splittable to 2×18kbit), new DSP cells; added new PLL blocks in addition to DCM blocks
Virtex-5 LX The base "logic optimized" version
Virtex-5 LXT Adds multi-gigabit transceiver support on top of LX (RocketIO GTP transceivers, 3.75 Gbit/s); also adds hard PCI Express (Gen1 ×8) and gigabit Ethernet MAC blocks
Virtex-5 SXT DSP-optimized version of Virtex-5: identical functionality to LXT, but with much higher DSP-to-logic ratio
Virtex-5 FXT Virtex-5 with GTX transceivers (6.5 Gbit/s) and hard PPC440 cores
Virtex-5 TXT 2009 Transceiver-optimized version of Virtex-5: has large amount of GTX transceivers (no PPC cores)
Virtex-6 2009 40nm 0.9V or 1.0V Replaces DCM blocks with MMCM blocks (which are an improved version of the existing PLL blocks), minor improvements to logic, DSP, block RAM, and IO cells
Virtex-6 LX The base "logic optimized" version
Virtex-6 LXT Adds multi-gigabit transceiver support on top of LX (GTX transceivers, up to 6.6 Gbit/s); also adds hard PCI Express (Gen2 ×8) and gigabit Ethernet MAC blocks
Virtex-6 SXT DSP-optimized version of Virtex-6; identical functionality to LXT, but with much higher DSP-to-logic ratio
Virtex-6 HXT Transceiver-optimized version of Virtex-6: replaces GTX transceivers with GTH transceivers (11.2 Gb/s)
Virtex-6 CXT Identical to LXT, but with some transceivers and hard PCI Express / Ethernet MAC blocks disabled
Spartan-6 Spartan-6 LX 2009 45nm 1.0V or 1.2V A low-end family built from an amalgamation of Spartan-3A and Virtex-6 features; has a LUT6-based logic cell, slightly improved Spartan-3A DSP cell, 18kbit block RAMs (splittable into 2×9kbit), improved DCM blocks, PLL blocks, IO blocks with serdes support; also has a new hard memory controller block
Spartan-6 LXT Spartan-6 version with multi-gigabit transceivers (GTP, 3.2 Gbit/s) and hard PCI Express (Gen 1 ×1) block
7 Series 2010 28nm 0.9V, 0.95V, or 1.0V A successor to the Virtex-6 family, with several separately-marketed sub-families that are made from essentially identical cells with a few exceptions; the IO cells have been split into two variants: HR (high range, 3.3V capable cells) and HP (high performance, 1.8V capable cells with DCI functionality)
Spartan 7 2017 Low-end logic-optimized parts, feature HRIO and no special blocks; several parts are identical to Artix parts with transceivers disabled
Artix-7 2010 Low-end parts, feature HRIO, GTP transceivers (6.6 Gbit/s), PCI-Express hard block (Gen 2.1 ×4)
Kintex-7 2010 Middle-end parts, feature HRIO and sometimes HPIO, GTX transceivers (12.5 Gbit/s), PCI-Express hard block (Gen 2.1 ×8)
Virtex-7 2010 High-end parts, feature HPIO and sometimes HRIO, GTX or GTH transceivers (13.1 Gbit/s), PCI-Express hard block (Gen 2.1 ×8 or Gen 3 ×8)
Virtex-7 3D 2011 First FPGA made of multiple die in one package, using a special interposer die for very fast and wide inter-die interconnect, essentially presenting as a single unified device made of several "super logic regions" (SLRs)
Virtex-7 HT 2012 Virtex-7 3D version that also adds special ultra-high-speed GTZ transceivers (28.05 Gbit/s) via a separate die in the same package
Zynq-7000 2011 An ARM Cortex-A9 based system on a chip integrated with an Artix-7 or a Kintex-7 FPGA on a single die
UltraScale 2013[24] 20nm 0.9V, 0.95V, or 1.0V A successor to 7 Series focused on scalability; features a new distributed clock distribution system as well as upgraded logic, DSP, and block RAM cells; hard blocks include the GTH transceivers (16.3 Gbit/s), GTY transceivers (30.5 Gbit/s), PCI Express (Gen3 ×8) blocks, 100G Ethernet MAC, 150G Interlaken blocks
Kintex UltraScale 2013 Middle-end parts
Virtex UltraScale 2014 High-end parts
UltraScale+ 2015 16nm 0.72V, 0.85V, or 0.9V An UltraScale upgrade with faster GTY transceivers (32.75 Gbit/s) and improved hard blocks (PCI Express Gen3 ×16 or Gen4 ×8); HR IO is gone and replaced with simpler HD (High Density) IO; some parts feature new UltraRAM (288kbit RAM) blocks
Artix UltraScale+ 2021 Low-end parts
Kintex UltraScale+ 2015 Middle-end parts
Virtex UltraScale+ 2016 High-end parts
Virtex UltraScale+ 58G Features new GTM transceivers (58 Gbit/s PAM4)
Virtex UltraScale+ HBM Features High Bandwidth Memory within the same package and an integrated hard memory controller inside the FPGA die
Zynq UltraScale+ MPSoC 2015 An ARM Cortex-A53 based system on a chip integrated with a Kintex UltraScale+ FPGA on the same die
Zynq UltraScale+ RFSoC 2017 Like the MPSoC, but adds RF-DAC and RF-ADC blocks for high-speed radios (5G technology)
Alveo 2018 Alveo is a series of accelerator boards that are built on UltraScale+-series FPGAs that are identical to some Kintex/Virtex/Zynq devices, but are nominally considered to be distinct chip models
Versal 2019 7nm 0.7V, 0.8V, or 0.88V An ARM Cortex-A72 based system on a chip integrated with a new version of FPGA fabric (with new logic, DSP, and block RAM cells), hard DDR memory controllers, and a network-on-chip (NoC) connecting all of the parts together
Versal Prime 2019 The base Versal parts
Versal AI Core 2019 Features the AI engine cores
Versal Premium Features high-bandwidth versions of the hard blocks

Note: The process information for early FPGA devices (before Virtex) may be inaccurate, due to the devices being subject to die shrink without changing the model name — the process listed above may not be the only process in which a given device has been manufactured.

Early FPGA devices

XC2000

The XC2000 devices have the following user-programmable blocks:[25]

  • CLBs (Configurable Logic Blocks): each CLB consists of two 3-input LUTs, a hard multiplexer combining LUT outputs (which can be used to combine them to a single 4-input LUT, among other things) and one flip-flop (with asynchronous set and reset capabilities)
  • User I/O blocks: each user I/O pin is associated with an I/O block, which consists of an input buffer, an input flip-flop, and a tri-state output buffer
  • One crystal oscillator amplifier
  • Two global clock buffers
Model CLBs User I/O (max)
XC2064, XC2064L 64 (8×8) 58
XC2018, XC2018L 100 (10×10) 74

Note: the available user I/O amount varies with chip packaging.

XC3000

The XC3000 devices have the following user-programmable blocks:[26]

  • CLBs (Configurable Logic Blocks): each CLB consists of two 4-input LUTs, a hard multiplexer combining LUT outputs (which can be used to combine them to a single 5-input LUT, among other things) and two flip-flops (with asynchronous set or reset capabilities)
  • User I/O blocks: each user I/O pin is associated with an I/O block, which consists of an input buffer, an input flip-flop, a tri-state output buffer, and an output flip-flop
  • Intra-FPGA tri-state buses, with tri-state buffers
  • One crystal oscillator amplifier
  • Two global clock buffers
Model CLBs User I/O (max) Tri-state buses Tri-state buffers per bus
XC3020, XC3020A, XC3020L, XC3120, XC3120A 64 (8×8) 64 16 9
XC3030, XC3030A, XC3030L, XC3130, XC3130A 100 (10×10) 80 20 11
XC3042, XC3042A, XC3042L, XC3142, XC3142A, XC3142L 144 (12×12) 96 24 13
XC3064, XC3064A, XC3064L, XC3164, XC3164A 224 (16×14) 120 32 15
XC3090, XC3090A, XC3090L, XC3190, XC3190A, XC3190L 320 (16×20) 144 40 17
XC3195, XC3195A 484 (22×22) 176 44 23

Note: the available user I/O amount varies with chip packaging.

XC4000, Spartan

The XC4000 and Spartan devices have the following user-programmable blocks:[27][28][29][30]

  • CLBs (Configurable Logic Blocks), each CLB containing:
    • two 4-input LUTs (F and G), which can be used as distributed RAM in 16×2 bit or 32×1 bit configurations (except on XC4000D devices)
    • a 3-input LUT (H) that can combine F and G outputs (for example, to implement a 5-input LUT)
    • two flip-flops (with clock enable and asynchronous set or reset)
    • carry chain logic
  • User I/O blocks, one for each user I/O pin:
    • input buffer
    • tri-state output buffer
    • programmable pull-up or pull-down
    • input flip-flop (except on XC4000H devices)
    • output flip-flop (except on XC4000H devices)
    • optional delay element
    • fast capture latch (on some devices)
    • output multiplexer (on some devices)
  • Edge decoders (essentially wide AND gates)
  • Intra-FPGA tri-state buses, with tri-state buffers
  • Global clock buffers
  • Miscellaneous configuration logic (startup and readback control, boundary scan logic allowing custom user JTAG opcodes)
XC4000 family feature comparison
Family Distributed RAM H-LUT inputs CLB flip-flop capabilities IOB capabilities Clock buffers
XC4000, XC4000A asynchronous 1×F, 1×G, 1×general routing Flip-flop input and output flip-flops 4 primary + 4 secondary global buffers
XC4000H no flip-flops
XC4000D none input and output flip-flops
XC4000E, XC4000L, Spartan synchronous or asynchronous write, asynchronous read 3× any choice of F, G, general routing input and output flip-flops with clock enable
XC4000EX, XC4000XL, XC4000XLA, XC4000XV Flip-flop or latch input and output flip-flops with clock enable, fast capture latch, output multiplexer 8 global buffers, 8 global low-skew buffers, 8 early clock buffers, 8 fast buffers
Spartan XL 8 global low-skew buffers
Model Family CLBs User I/O (max)
XC4002A XC4000A 64 (8×8) 64
XC4002XL XC4000XL 64 (8×8) 64
XC4003 XC4000 100 (10×10) 80
XC4003A XC4000A 100 (10×10) 80
XC4003H XC4000H 100 (10×10) 160
XC4003E XC4000E 100 (10×10) 80
XCS05 Spartan 100 (10×10) 77
XCS05XL Spartan XL 100 (10×10) 77
XC4004A XC4000A 144 (12×12) 96
XC4005 XC4000 196 (14×14) 112
XC4005A XC4000A 196 (14×14) 112
XC4005H XC4000H 196 (14×14) 192
XC4005E XC4000E 196 (14×14) 112
XC4005L XC4000L 196 (14×14) 112
XC4005XL XC4000XL 196 (14×14) 112
XCS10 Spartan 196 (14×14) 112
XCS10XL Spartan XL 196 (14×14) 112
XC4006 XC4000 256 (16×16) 128
XC4006E XC4000E 256 (16×16) 128
XC4008 XC4000 324 (18×18) 144
XC4008E XC4000E 324 (18×18) 144
XC4010 XC4000 400 (20×20) 160
XC4010D XC4000D 400 (20×20) 160
XC4010E XC4000E 400 (20×20) 160
XC4010L XC4000L 400 (20×20) 160
XC4010XL XC4000XL 400 (20×20) 160
XCS20 Spartan 400 (20×20) 160
XCS20XL Spartan XL 400 (20×20) 160
XC4013 XC4000 576 (24×24) 192
XC4013D XC4000D 576 (24×24) 192
XC4013E XC4000E 576 (24×24) 192
XC4013L XC4000L 576 (24×24) 192
XC4013XL XC4000XL 576 (24×24) 192
XC4013XLA XC4000XLA 576 (24×24) 192
XCS30 Spartan 576 (24×24) 192
XCS30XL Spartan XL 576 (24×24) 192
XC4020E XC4000E 784 (28×28) 224
XC4020XL XC4000XL 784 (28×28) 224
XC4020XLA XC4000XLA 784 (28×28) 224
XCS40 Spartan 784 (28×28) 205
XCS40XL Spartan XL 784 (28×28) 205
XC4025E XC4000E 1024 (32×32) 256
XC4028EX XC4000EX 1024 (32×32) 256
XC4028XL XC4000XL 1024 (32×32) 256
XC4028XLA XC4000XLA 1024 (32×32) 256
XC4036EX XC4000EX 1296 (36×36) 288
XC4036XL XC4000XL 1296 (36×36) 288
XC4036XLA XC4000XLA 1296 (36×36) 288
XC4044XL XC4000XL 1600 (40×40) 320
XC4044XLA XC4000XLA 1600 (40×40) 320
XC4052XL XC4000XL 1936 (44×44) 352
XC4052XLA XC4000XLA 1936 (44×44) 352
XC4062XL XC4000XL 2304 (48×48) 384
XC4062XLA XC4000XLA 2304 (48×48) 384
XC4085XL XC4000XL 3136 (56×56) 448
XC4085XLA XC4000XLA 3136 (56×56) 448
XC40110XV XC4000XV 4096 (64×64) 448
XC40150XV XC4000XV 5184 (72×72) 448
XC40200XV XC4000XV 7056 (84×84) 448
XC40250XV XC4000XV 8464 (92×92) 448

Note: the available user I/O amount varies with chip packaging.

XC5200

The XC5200 devices have the following user-programmable blocks:[31]

  • CLBs (Configurable Logic Blocks): each CLB consists of 4 LCs (logic cells). Each logic cell consists of one 4-input LUT, a carry chain multiplexer, and one flip-flop (with clock enable and asynchronous reset). The CLB also has two dedicated multiplexers that can combine outputs of adjacent LCs (which can be used, among other purposes, to effectively combine the two 4-input LUTs into a 5-input LUT)
  • User I/O blocks: each user I/O pin is associated with an I/O block, which consists of an input buffer and a tri-state output buffer
  • Intra-FPGA tri-state buses, with tri-state buffers
  • One crystal oscillator amplifier
  • Four global clock buffers, one in each corner
  • Miscellaneous configuration logic (startup and readback control, boundary scan logic allowing custom user JTAG opcodes)
Model CLBs User I/O (max)
XC5202, XC5202L 64 (10×10) 84
XC5204 120 (10×12) 124
XC5206, XC5206L 196 (14×14) 148
XC5210 324 (18×18) 196
XC5216, XC5216L 484 (22×22) 244

Note: the available user I/O amount varies with chip packaging.

XC6200

The XC6200 family is unusual in several ways:[32]

  • as opposed to other early FPGAs where a design always takes up the whole device and is synthesized once, then usually stored in flash storage, XC6200 is dynamically reconfigurable in arbitrarily small chunks (down to a single logic cell), and is meant to be used along with an external CPU that can modify parts of design in real time
  • the logic is not LUT based; instead, every logic cell consists of a 2-to-1 MUX whose inputs can be inverted or tied to constants (to implement arbitrary 2-input logic function) and a flip-flop
  • the routing structure is fully documented, unusually simple, and hierarchical in nature, with the device made of 16×16 cell tiles and 4×4 cell blocks
  • the configuration data format is likewise fully documented in the data sheet,[32] allowing (and encouraging) users to create logic designs without using vendor tools
  • the part of configuration RAM that corresponds to unused area of circuit is explicitly allowed to be used for unrelated data storage
Model Logic cells IOBs Configuration RAM (bits) Notes
XC6209 2304 (48×48) 192 36K listed as planned product, unclear if it ever reached production
XC6216 4096 (64×64) 256 65K
XC6236 9216 (96×96) 384 147K listed as planned product, unclear if it ever reached production
XC6264 16384 (128×128) 512 262K listed as planned product, unclear if it ever reached production

XC8100

The XC8100 family is unusual in several ways:[32]

  • The configuration storage is made of one-time programmable antifuses, as opposed to other FPGAs (which use RAM cells and need to have configuration reuploaded upon power-up) and to CPLDs (which use non-volatile but multiple time programmable EPROM/EEPROM/flash storage).
  • The logic is not LUT based; instead, the device is made of logic cells, which have 4 general inputs (+1 cascade input), 1 general output (+1 cascade output) and can be configured as either an AND gate or a sum-of-products, whose inputs can be inverted or tied to constants. This arrangement allows, as special cases, construction of a 2-input MUX or a D latch within a single cell, or combining two cells configured as D latches to construct a D flip-flop.
Model Logic cells User I/O (max) Notes
XC8100 192 (24×8) 32
XC8101 384 (24×16) 72
XC8103 1024 (32×32) 128
XC8106 1728 (48×36) 168
XC8109 2688 (56×48) 192
XC8112 3744 248 planned product that never reached production
XC8116 4800 280 planned product that never reached production
XC8120 6144 320 planned product that never reached production

Virtex, Spartan-II

The Virtex and Spartan-II devices are made of the following user-programmable blocks:

  • CLBs (configurable logic blocks), each made of two mostly-independent SLICEs, where a SLICE contains:
    • two 4-input LUTs, which can also be used as 16-bit distributed RAMs (which can be combined into 16×2 or 32×1 single-port or 16×1 dual port arrangements), or as 16-bit shift registers (which can be cascaded together to make longer shift registers)
    • carry chain logic consisting of two MUXCY+XORCY cell pairs, for construction of efficient ALUs or wide logic functions
    • two MULT_AND cells, to be combined with MUXCY+XORCY for construction of efficient multipliers
    • two hard multiplexer cells (MUXF5 and MUXF6) that can combine the LUT outputs together, allowing for efficient multiplexer tree construction or for construction of wider LUTs (5-input LUT out of two 4-input LUTs, or 6-input LUT out of four 4-input LUTs)
    • two flip-flops with clock enable and (configurable as synchronous or asynchronous) set and reset inputs; they can also be used as latches
  • Intra-FPGA tri-state buses with tri-state buffers (two buffers per CLB)
  • 4kbit true dual port block RAMs, which can be used in 4096×1, 2048×2, 1024×4, 512×8, or 256×16 configurations
  • IOBs (I/O blocks), one per user I/O pin, containing:
    • several kinds of input buffer (selectable by user):
      • plain CMOS input buffer
      • differential input buffer using a VREF (voltage reference) pin for advanced I/O standards
      • (Virtex-E and Spartan-IIE only) differential input buffer using a pair of I/O pins for differential I/O standards (which has to be selected from a predefined list of pairs — each IOB has its associated other IOB that can be used to construct a differential pair)
    • tristate output buffer
    • configurable pull-up, pull-down, or keeper circuit
    • three flip-flops (for input, output, tristate enable), identical to the ones in CLBs
  • the IOBs are grouped into 8 I/O banks (2 for each edge of the device), with each bank having a separate power supply, allowing for usage of several I/O standards with conflicting voltage requirements in a single device
  • DLLs (delay-locked loops) that can be used to phase-align, deskew, and phase-shift incoming clock signals
  • 4 global clock buffers
  • miscellaneous configuration logic (startup control, readback data capture, JTAG control)

The Virtex and Spartan-II devices are functionally identical to each other and differ only in available size range, performance, and packaging options. The Spartan-IIE devices use the same die as the corresponding Virtex E devices, but have some block RAM and DLLs disabled.

Model Family CLBs 4-LUTs

(CLBs×4)

Block RAMs (4kbit each) User I/O (max) User I/O differential pairs (max) DLLs
XC2S15 Spartan-II[33] 96 (12×8) 384 4 86 - 4
XC2S30 Spartan-II 216 (18×12) 864 6 92 - 4
XCV50 Virtex[34] 384 (24×16) 1536 8 180 - 4
XC2S50 Spartan-II 384 (24×16) 1536 8 176 - 4
XCV50E Virtex E[35] 384 (24×16) 1536 16 176 83 8
XC2S50E Spartan-IIE[36] 384 (24×16) 1536 8 182 83 4
XCV100 Virtex 600 (30×20) 2400 10 180 - 4
XC2S100 Spartan-II 600 (30×20) 2400 10 176 - 4
XCV100E Virtex E 600 (30×20) 2400 20 196 83 8
XC2S100E Spartan-IIE 600 (30×20) 2400 10 202 86 4
XCV150 Virtex 864 (36×24) 3456 12 260 - 4
XC2S150 Spartan-II 864 (36×24) 3456 12 260 - 4
XC2S150E Spartan-IIE 864 (36×24) 3456 12 265 114 4
XCV200 Virtex 1176 (42×28) 4704 14 284 - 4
XC2S200 Spartan-II 1176 (42×28) 4704 14 284 - 4
XCV200E Virtex E 1176 (42×28) 4704 28 284 119 8
XC2S200E Spartan-IIE 1176 (42×28) 4704 14 289 120 4
XCV300 Virtex 1536 (48×32) 6144 16 316 - 4
XCV300E Virtex E 1536 (48×32) 6144 32 316 137 8
XC2S300E Spartan-IIE 1536 (48×32) 6144 16 329 120 4
XCV400 Virtex 2400 (60×40) 9600 20 404 - 4
XCV400E Virtex E 2400 (60×40) 9600 40 404 183 8
XC2S400E Spartan-IIE 2400 (60×40) 9600 40 410 172 4
XCV405E Virtex EM[37] 2400 (60×40) 9600 140 404 183 8
XCV600 Virtex 3456 (72×48) 13824 24 512 - 4
XCV600E Virtex E 3456 (72×48) 13824 72 512 247 8
XC2S600E Spartan-IIE 3456 (72×48) 13824 72 514 205 4
XCV800 Virtex 4704 (84×56) 18816 28 512 - 4
XCV812E Virtex EM 4704 (84×56) 18816 280 556 201 8
XCV1000 Virtex 6144 (96×64) 24576 32 512 - 4
XCV1000E Virtex E 6144 (96×64) 24576 96 660 281 8
XCV1600E Virtex E 7776 (108×72) 31104 144 724 344 8
XCV2000E Virtex E 9600 (120×80) 38400 160 804 344 8
XCV2600E Virtex E 12696 (138×92) 50784 184 804 344 8
XCV3000E Virtex E 16224 (156×104) 64896 208 804 344 8

Note: the available user I/O amount varies with chip packaging. Additionally, not all I/Os can be used as part of a differential pair, so the available differential pair count can be smaller than half of the available I/O count.

Virtex-II

The Virtex-II devices are made of the following user-programmable blocks:

  • CLBs (configurable logic blocks), which contain 4 logic SLICEs, which are an improved version of the Virtex SLICE, with the following differences:
    • when used as distributed RAM, the LUTs of multiple SLICEs within a CLB can be combined to obtain the following RAM configurations:
      • 16×1 single port (half SLICE)
      • 16×2 single port (one SLICE)
      • 32×1 single port (one SLICE)
      • 64×1 single port (two SLICEs)
      • 128×1 single port (four SLICEs)
      • 16×1 dual port (two half-SLICEs — utilizes one LUT of two different SLICEs each)
      • 16×2 dual port (two SLICEs)
      • 32×1 dual port (two SLICEs)
      • 64×1 dual port (four SLICEs)
    • the wide function multiplexers can now be used in a 4-level tree (as opposed to a 2-level tree on Virtex), allowing for construction of up to 8-input LUTs (out of 16 4-input LUTs from two neighbouring CLBs)
    • the carry chain has been enhanced with the addition of an ORCY cell allowing for efficient sum-of-products mapping
  • 18kbit true dual port block RAMs, which can be used in 16386×1, 8192×2, 4096×4, 2048×9, 1024×18, 512×36 configurations (with the narrow configurations having only 16kbit available, since they cannot access the parity bits)
  • hard multiplier blocks (two signed 18-bit inputs, 36-bit output) — always exactly one per block RAM, since they reside in a shared tile
  • IOBs (I/O blocks), one per user I/O pin, which are an improved version of the Virtex IOB with the following differences:
    • the three I/O flip-flops are replaced with pairs of flip-flops for DDR (double data rate) capability
    • new DCI (Digitally Controlled Impedance) functionality — the device has a per-bank circuit that can utilize an external precision resistor pair connected to user I/O pins to calibrate I/O resistance on remaining user pins, providing very good impedance matching
    • support for multiple new I/O standards, including native differential I/O
  • DCMs (digital clock managers), which replace Virtex DLLs, adding frequency synthesis and clock divider capability
  • 16 global clock buffers
  • Miscellaneous configuration logic (startup control, readback data capture, JTAG control, and the ICAP — Internal Configuration Access Port). The ICAP can be used to dynamically reprogram parts of the FPGA after the initial configuration from within the FPGA itself.

Virtex-II Pro devices include some additional blocks:

  • RocketIO transceivers: high-speed parallel-to-serial transmitters and serial-to-parallel receivers with clock data recovery and 8b/10b encoders/decoders. They have a speed range of 600 Mb/s to 3.125 Gb/s and parallel width of 8, 16, or 32 bits (or 10, 20, 40 bits in 8b10b bypass mode)
  • RocketIO X transceivers: improved transceivers with 64b/66b encoding/decoding (in addition to 8b/10b), speed range of 2.488 Gb/s to 6.25 Gb/s (XC2VPX20) or fixed speed of 4.25 Gb/s (XC2VPX70), and parallel width of 8, 16, 32, or 64 bits (or 10, 20, 40, 80 bits in 8b/10b bypass mode)
  • Embedded PPC405 cores
Model Family CLBs 4-LUTs (CLBs×8) Multiplier blocks and block RAMs (18kbit each) DCMs User I/O (max) Multi-gigabit transceivers (max) PPC cores
XC2V40 Virtex-II[38] 64 (8×8) 512 4 4 88 - -
XC2V80 Virtex-II 128 (8×16) 1024 8 4 120 - -
XC2V250 Virtex-II 384 (16×24) 3072 24 8 200 - -
XC2V500 Virtex-II 768 (24×32) 6144 32 8 264 - -
XC2V1000 Virtex-II 1280 (32×40) 10240 40 8 432 - -
XC2V1500 Virtex-II 1920 (40×48) 15360 48 8 528 - -
XC2V2000 Virtex-II 2688 (48×56) 21504 56 8 624 - -
XC2V3000 Virtex-II 3584 (56×64) 28672 96 12 720 - -
XC2V4000 Virtex-II 5760 (72×80) 46080 120 12 912 - -
XC2V6000 Virtex-II 8448 (88×96) 67584 144 12 1104 - -
XC2V8000 Virtex-II 11648 (104×112) 93184 168 12 1108 - -
XC2VP2 Virtex-II Pro[39] 352 2816 12 4 204 RocketIO ×4 -
XC2VP4 Virtex-II Pro 752 6016 28 4 348 RocketIO ×4 1
XC2VP7 Virtex-II Pro 1232 9856 44 4 396 RocketIO ×8 1
XC2VP20 Virtex-II Pro 2320 18560 88 8 564 RocketIO ×8 2
XC2VPX20 Virtex-II Pro X 2448 19584 88 8 552 RocketIO X ×8 1
XC2VP30 Virtex-II Pro 3424 27392 136 8 644 RocketIO ×8 2
XC2VP40 Virtex-II Pro 4848 38784 192 8 804 RocketIO ×12 2
XC2VP50 Virtex-II Pro 5904 47232 232 8 852 RocketIO ×16 2
XC2VP70 Virtex-II Pro 8272 66176 328 8 996 RocketIO ×20 2
XC2VPX70 Virtex-II Pro X 8272 66176 308 8 992 RocketIO X ×20 2
XC2VP100 Virtex-II Pro 11024 88192 444 12 1164 RocketIO ×20 2

Note: the available user I/O and multi-gigabit transceiver amount varies with chip packaging.

Note: the CLB count for Virtex-II Pro devices is no longer a simple columns×rows multiplication, as the CLB grid contains holes for the PowerPC cores.

Spartan-3

The Spartan-3 devices are made of:

  • CLBs (configurable logic blocks), which are very similar to Virtex-II, with some modifications:
    • Only two of the four SLICEs in the CLB can now be used as distributed RAM or shift registers. The SLICEs that can be used as distributed RAM or shift registers are called SLICEMs, and the remaining SLICEs are called SLICELs.
    • The available distributed RAM configurations are now:
      • 16×1 single port (half SLICEM)
      • 16×2 single port (one SLICEM)
      • 32×1 single port (one SLICEM)
      • 64×1 single port (two SLICEMs)
      • 16×1 double port (one SLICEM)
      • 32×1 double port (two SLICEMs)
    • The ORCY cell has been removed
  • 18kbit true dual port block RAMs, with the following variants:
    • Spartan-3, Spartan-3E: identical to Virtex-II
    • Spartan-3A, Spartan-3AN: adds per-byte write enable signals
    • Spartan-3A DSP: like Spartan-3A, plus adds optional output pipeline registers (for faster clock-to-out time)
  • hard multiplier blocks or DSP cells:
    • Spartan-3: MULT18X18, identical to Virtex-II
    • Spartan-3E, Spartan-3A, Spartan-3AN: MULT18X18SIO, adds extra input registers for faster pipelined operation
    • Spartan-3A DSP: DSP48A, a complete DSP ALU consisting of an 18×18 multiplier plus 48-bit accumulator
  • IOBs (I/O blocks), one per user pin:
    • Spartan-3: similar to Virtex-II, arranged in 8 banks
    • Spartan-3E: simplified version, removes DCI capability, arranged in 4 banks (one for each device edge)
    • Spartan-3A, Spartan-3AN, Spartan-3A DSP: like Spartan-3E, but with support for newer I/O standards, and with somewhat differing capabilities of top/bottom banks and left/right banks
  • DCMs, similar to Virtex-II
  • 8 (Spartan-3) or 24 (Spartan-3E, 3A, 3AN, 3A DSP) global clock buffers
  • Miscellaneous configuration logic (like Virtex-II, but with disabled ICAP access)
  • Spartan-3A, 3AN, 3A DSP only: access to a unique device serial number (so-called device DNA)
  • Spartan-3AN only: access port to the in-package SPI flash
Model Family CLBs 4-LUTs (CLBs×8) Block RAMs (18kbit each) Multiplier blocks DCMs User I/O (max) Differential I/O pairs (max)
XC3S50 Spartan-3[40] 192 (12×16) 1536 4 4 2 124 56
XC3S200 Spartan-3 480 (20×24) 3840 12 12 4 173 76
XC3S400 Spartan-3 896 (28×32) 7168 16 16 4 264 116
XC3S1000, XC3S1000L Spartan-3 1920 (40×48) 15360 24 24 4 391 175
XC3S1500, XC3S1500L Spartan-3 3328 (52×64) 26624 32 32 4 487 221
XC3S2000 Spartan-3 5120 (64×80) 40960 40 40 4 565 270
XC3S4000 Spartan-3 6912 (72×96) 55296 96 96 4 633 300
XC3S5000 Spartan-3 8320 (80×104) 66560 104 104 4 633 300
XC3S100E Spartan-3E[41] 240 1920 4 4 2 108 40
XC3S250E Spartan-3E 612 4896 12 12 4 172 68
XC3S500E Spartan-3E 1164 9312 20 20 4 232 92
XC3S1200E Spartan-3E 2168 17344 28 28 8 304 124
XC3S1600E Spartan-3E 3688 29504 36 36 8 376 156
XC3S50A, XC3S50AN Spartan-3A/3AN[42] 176 1408 3 3 2 144 64
XC3S200A, XC3S200AN Spartan-3A/3AN 448 3584 16 16 4 248 112
XC3S400A, XC3S400AN Spartan-3A/3AN 896 7168 20 20 4 311 142
XC3S700A, XC3S700AN Spartan-3A/3AN 1472 11776 20 20 8 372 165
XC3S1400A, XC3S1400AN Spartan-3A/3AN 2816 22528 32 32 8 502 227
XC3SD1800A Spartan-3A DSP[43] 4160 33280 84 DSP48A ×84 8 519 227
XC3SD3400A Spartan-3A DSP 5968 47744 126 DSP48A ×126 8 469 213

Note: the available user I/O amount varies with chip packaging. Additionally, not all I/Os can be used as part of a differential pair, so the available differential pair count can be smaller than half of the available I/O count.

Note: for families other than Spartan-3, the CLB grid is irregular and includes holes for block RAMs and DCMs, so the CLB count is not a simple multiplication of columns×rows

Virtex-4

The Virtex-4 devices are made of:[44][45]

  • CLBs (configurable logic blocks), almost unchanged from Spartan-3
  • 18kbit true dual port block RAMs, very similar to Spartan-3A DSP, but with some new capabilities:
    • two adjacent block RAMs can be combined to make a 32768×1 RAM
    • each block RAM can be used in FIFO mode (in 4096×4, 2048×9, 1024×18, 512×36 configurations) where address inputs are replaced with hardware FIFO counter functionality
  • DSP48 blocks,[46] ALU blocks with 18×18 multiplier and 48-bit accumulator
  • IOBs (I/O blocks, one per user pin): in addition to Virtex-II capabilities, they support ISERDES and OSERDES blocks which do simple serial-to-parallel and parallel-to-serial conversion (2, 3, 4, 5, 6, 7, or 8 bit wide in SDR mode; 4, 6, 8, or 10 bit wide in DDR mode)
  • IOBs are arranged into I/O banks; in a change from earlier FPGAs with fixed bank number, number of I/O banks on Virtex-4 varies with device size, but banks now have a more uniform size of 16 or 32 I/O pins, with the exception of special bank 0 that contains dedicated configuration pins. Each bank has two or four I/O clock buffers for fast clocks used by the SERDES blocks.
  • DCMs, similar to Virtex-II/Spartan-3
  • PMCDs (phase-matched clock dividers), an unusual clock divider block
  • 32 global clock buffers
  • Multiple clock regions, with 2 regional clock buffers per region
  • Miscellaneous configuration logic: like Virtex-II, plus:
    • configuration data ECC checking circuitry
    • 32-bit user data access port

The Virtex-4 FX devices additionally contain:

  • RocketIO multi-gigabit transceivers with a speed range of 622 Mb/s to 6.5 Gb/s and parallel width of 8, 16, 32, or 64 bits (10, 20, 40, or 80 bits in 8b/10b bypass mode)
  • Embedded PPC405 cores
  • Embedded gigabit ethernet MAC blocks (two per PPC core)
Model Sub-family CLBs 4-LUTs (CLBs×8) Block RAMs (18kbit each) DSP48 blocks DCMs PMCDs Clock Regions I/O banks User I/Os (max) Gigabit transceivers (max) PPC cores
XC4VLX15 LX 1536 (24×64) 12288 48 32 4 - 8 9 320 - -
XC4VLX25 LX 2688 (28×96) 21504 72 48 8 4 12 11 448 - -
XC4VLX40 LX 4608 (36×128) 36864 96 64 8 4 16 13 640 - -
XC4VLX60 LX 6656 (52×128) 53248 160 64 8 4 16 13 640 - -
XC4VLX80 LX 8960 (56×160) 71680 200 80 12 8 20 15 768 - -
XC4VLX100 LX 12288 (64×192) 98304 240 96 12 8 24 17 960 - -
XC4VLX160 LX 16896 (88×192) 135168 288 96 12 8 24 17 960 - -
XC4VLX200 LX 22272 (116×192) 178176 336 96 12 8 24 17 960 - -
XC4VSX25 SX 2560 (40×64) 20480 128 128 4 - 8 9 420 - -
XC4VSX35 SX 3840 (40×96) 30720 192 192 8 4 12 11 448 - -
XC4VSX55 SX 6144 (48×128) 49152 320 512 8 4 16 13 640 - -
XC4VFX12 FX 1368 10944 36 32 4 - 8 9 320 - 1
XC4VFX20 FX 2136 17088 68 32 4 - 8 9 320 8 1
XC4VFX40 FX 4656 37248 144 48 8 4 12 11 448 12 2
XC4VFX60 FX 6320 50560 232 128 12 8 16 13 576 16 2
XC4VFX100 FX 10544 84352 376 160 12 8 20 15 768 20 2
XC4VFX140 FX 15792 126336 552 192 20 8 24 17 896 24 2

Note: the I/O banks count includes special bank 0, which contains only dedicated configuration I/O (no user I/O)

Note: the available user I/O, I/O bank, and multi-gigabit transceiver amount varies with chip packaging.

Note: the CLB count for FX devices is no longer a simple columns×rows multiplication, as the CLB grid contains holes for the PowerPC cores.

Virtex-5

The Virtex-5 devices are made of:[47][48]

  • CLBs (configurable logic blocks) with a new, 6-input-LUT based construction:
    • every CLB is made of two SLICEs — either two SLICELs or one SLICEL and one SLICEMs; the exact proportion of SLICEMs in a device varies, but at least 50% of CLBs contain a SLICEM (with a higher proportion on DSP-heavy devices)
    • every SLICE contains four 6-input LUTs, each of which can be used as:
      • a 6-input LUT
      • two 5-input LUTs with shared inputs (ie. the LUT is fracturable)
      • (SLICEM only) 32×2 or 64×1 distributed RAM, which can be combined with other distributed RAMs within the same SLICEM
      • (SLICEM only) 16-bit or 32-bit shift register, which can be combined with other shift registers within the same SLICEM, for maximum of 128-bit shift register in a single SLICEM
    • the arrangement of distributed RAMs within the SLICEM is quite complex and only some configurations can be obtained; the SLICEM usage combinations allowed by vendor tools are:
      • 32×8, 64×4, 128×2, or 256×1 single port RAM
      • 32×4, 62×2, 128×1 dual port RAM
      • 32×2, 64×1 quad port RAM
      • 32×6, 64×3 simple dual port RAM
    • every SLICE contains four flip-flops with clock enable and (configurable as synchronous or asynchronous) set and reset inputs; they can also be used as latches
    • every SLICE contains a carry chain, identical in functionality to the one used since Virtex (made of MUXCY and XORCY cells), but now represented as a single CARRY4 cell for the whole SLICE (mostly for more accurate timing simulation)
    • compared to Virtex-4 SLICEs, the MULT_AND cell is gone; however, its functionality can be trivially replicated by using one half of the corresponding now-fracturable LUT
    • every SLICE contains a two-level tree of wide LUT multiplexers that can be used to combine the outputs of the LUTs, and can eg. combine the four LUTs within a SLICE into a single 8-input LUT
  • 36kbit splittable true dual port block RAMs, with some new capabilities compared to Virtex-4:
    • the base block RAM is twice the size of Virtex-4; however, any given block RAM can be split into two 18kbit halves functioning independently (but only one half can use the hardware FIFO mode)
    • the available true dual port configurations of the full (36kbit) block RAM are: 32768×1, 16384×2, 8192×4, 4096×9, 2048×18, 1024×36, plus a special 65536×1 mode obtained by combining two adjacent RAMs
    • the available true dual port configurations of the half (18kbit) block RAM are: 16384×1, 8192×2, 4096×4, 2048×9, 1024×18
    • in addition to true dual port mode, the block RAMs can also be used in simple dual port mode, which doubles the maximum width of the block RAM, allowing for 512×72 (full block RAM) and 512×36 (half block RAM) configurations
    • a hardware 64-bit SECDED ECC encoder/decoder has been added, which can be used with the simple dual port mode of the full block RAM to obtain a 512×64 block RAM with error correction and detection
  • DSP48E blocks,[49] improved version of Virtex-4 DSP48 blocks with 25×18 multiplier, 48-bit accumulator (with new bitwise operations function), and pattern detector
  • IOBs (I/O blocks, one per user pin): with minor improvements from Virtex-4 (mainly new I/O standard support)
  • The I/O bank arrangement is similar to Virtex-4, but the banks have size of 20 or 40 user I/O pins
  • CMTs (clock management tiles), each of which has:
    • two DCMs (similar to Virtex-4 DCM)
    • one PLL, which has similar general functionality as the old DCM, but is made of analog circuitry and has different set of available outputs
  • the Virtex-4 PMCDs are gone; some of their functionality can be replicated by using PLLs instead
  • 32 global clock buffers
  • multiple clock regions, with two regional clock buffers per region
  • a single system monitor: an analog-to-digital converter used for monitoring FPGA supply voltages, temperature, and possibly other, external analog signals
  • Miscellaneous configuration logic: like Virtex-4, plus:
    • unique device serial number access (identical to the DNA port in Spartan-3A)
    • read-only access to user-programmable efuses
  • (LXT and SXT devices) GTP[50] multi-gigabit transceivers with a speed range of 100 Mb/s to 3.75 Gb/s and parallel width of 8, or 16 bits (10 or 20 bits in 8b/10b bypass mode)
  • (FXT and TXT devices) GTX[51] multi-gigabit transceivers with a speed range of 150 Mb/s to 6.5 Gb/s and parallel width of 8, 16, or 32 bits (10, 20, or 40 bits in 8b/10b bypass mode)
  • (FXT devices) embedded PPC440 cores
  • (LXT, SXT, FXT, TXT devices) embedded gigabit Ethernet MAC cores
  • (LXT, SXT, FXT, TXT devices) embedded PCI Express cores capable of Gen1.1 ×8 operation
Model Sub-family CLBs 6-LUTs (=CLBs×8) SLICEMs Block RAMs (36kbit each) DSP48E blocks DCMs PLLs Clock regions I/O banks (max) User I/Os (max) Gigabit transceivers (max) PPC cores Ethernet MACs PCI Express cores
XC5VLX20T LXT 1560 (26×60) 12480 840 26 24 2 1 6 7 172 4 GTP - 2 1
XC5VLX30 LX 2400 (30×80) 19200 1280 32 32 4 2 8 13 400 - - - -
XC5VLX30T LXT 2400 (30×80) 19200 1280 36 32 4 2 8 12 360 8 GTP - 4 1
XC5VLX50 LX 3600 (30×120) 28800 1920 48 48 12 6 12 17 560 - - - -
XC5VLX50T LXT 3600 (30×120) 28800 1920 60 48 12 6 12 15 480 12 GTP - 4 1
XC5VLX85 LX 6480 (54×120) 51840 3360 96 48 12 6 12 17 560 - - - -
XC5VLX85T LXT 6480 (54×120) 51840 3360 108 48 12 6 12 15 480 12 GTP - 4 1
XC5VLX110 LX 8640 (64×160) 69120 4480 128 64 12 6 16 23 800 - - - -
XC5VLX110T LXT 8640 (64×160) 69120 4480 148 64 12 6 16 20 680 16 GTP - 4 1
XC5VLX155 LX 12160 (76×160) 97280 6560 192 128 12 6 16 23 800 - - - -
XC5VLX155T LXT 12160 (76×160) 97280 6560 212 128 12 6 16 20 680 16 GTP - 4 1
XC5VLX220 LX 17280 (108×160) 138240 9120 192 128 12 6 16 23 800 - - - -
XC5VLX220T LXT 17280 (108×160) 138240 9120 212 128 12 6 16 20 680 16 GTP - 4 1
XC5VLX330 LX 25920 (108×240) 207360 13680 288 192 12 6 24 33 1200 - - - -
XC5VLX330T LXT 25920 (108×240) 207360 13680 324 192 12 6 24 27 960 20 GTP - 4 1
XC5VSX35T SXT 2720 (34×80) 21760 2080 84 192 4 2 8 12 360 8 GTP - 4 1
XC5VSX50T SXT 4080 (34×120) 32640 3120 132 288 12 6 12 15 480 12 GTP - 4 1
XC5VSX95T SXT 7360 (46×160) 58880 6080 244 640 12 6 16 19 640 16 GTP - 4 1
XC5VSX240T SXT 18720 (78×240) 149760 16800 516 1056 12 6 24 27 960 24 GTP - 4 1
XC5VTX150T TXT 11600 (58×200) 92800 6000 228 80 12 6 20 20 680 40 GTX - 4 1
XC5VTX240T TXT 18720 (78×240) 149760 9600 324 96 12 6 24 20 680 48 GTX - 4 1
XC5VFX30T FXT 2560 20480 1520 68 64 4 2 8 12 360 8 GTX 1 4 1
XC5VFX70T FXT 5600 44800 3280 148 128 12 6 16 19 640 16 GTX 1 4 3
XC5VFX100T FXT 8000 64000 4960 228 256 12 6 16 20 680 16 GTX 2 4 3
XC5VFX130T FXT 10240 81920 6320 298 320 12 6 20 24 840 20 GTX 2 6 3
XC5VFX200T FXT 15360 122880 9120 456 384 12 6 24 27 960 24 GTX 2 8 4

Note: the I/O banks count includes special bank 0, which contains only dedicated configuration I/O (no user I/O)

Note: the available user I/O, I/O bank, and multi-gigabit transceiver amount varies with chip packaging.

Note: the CLB count for FXT devices is no longer a simple columns×rows multiplication, as the CLB grid contains holes for the PowerPC cores.

Virtex-6

The Virtex-6 devices are made of:[52]

  • CLBs (configurable logic blocks):[53] like the Virtex-5 CLBs, with some minor modifications:
    • every SLICE now contains 8 flip-flops (two for each 6-LUT) instead of 4
    • the flip-flops now have only one set/reset input (ie. it is impossible to have a flip-flop with both a set and a reset input)
  • 36 Kibit splittable true dual port block RAM:[54] a slightly improved version of the Virtex-5 block RAM
  • DSP48E1 blocks,[55] upgraded version of Virtex-5 DSP48E, adding a pre-adder block
  • IOBs (I/O blocks, one per user pin):[56] with minor improvements from Virtex-5 (mainly new I/O standard support), and with notable removal of 3.3 V I/O support (max supported I/O voltage is 2.5V)
  • The I/O bank arrangement is similar to Virtex-5, but the banks have constant size of 40 user I/O pins
  • CMTs (clock management tiles),[57] each of which contains two MMCMs (mixed-mode clocking managers), which are analog-based replacements for the old DCMs, and are an evolution of the Virtex-5 PLLs
  • 32 global clock buffers
  • multiple clock regions, with two or four regional clock buffers per region
  • a single system monitor, like Virtex-5
  • Miscellaneous configuration logic: like Virtex-5
  • (non-LX devices) GTX multi-gigabit transceivers with a speed range of 480 Mb/s to 6.6 Gb/s and parallel width of 8, 16, or 32 bits (10, 20, or 40 bits in 8b/10b bypass mode)
  • (some HXT devices) GTH multi-gigabit transceivers with a speed range of 2.488 Gb/s to 11.2 Gb/s and parallel width of 8, 16, 32, or 64 bits (10, 20, 40, or 80 bits in 8b/10b bypass mode)
  • (non-LX devices) embedded gigabit Ethernet MAC cores
  • (non-LX devices) embedded PCI Express cores capable of Gen2 ×8 operation
Model Sub-family CLBs 6-LUTs (=CLBs×8) SLICEMs 36 Kibit block RAMs DSP48E1 blocks MMCMs Clock Regions I/O banks (max) User I/Os (max) Gigabit transceivers (max) Ethernet MACs PCI Express Cores
XC6VLX75T LXT 5820 46560 4180 156 288 6 6 9 360 12 GTX 4 1
XC6VCX75T CXT[58] 5820 46560 4180 156 288 6 6 9 360 12 GTX 1 1
XC6VLX130T LXT 10000 80000 6960 264 480 10 10 15 600 20 GTX 4 2
XC6VCX130T CXT 10000 80000 6960 264 480 10 10 15 600 16 GTX 1 2
XC6VLX195T LXT 15600 124800 12160 344 640 10 10 15 600 20 GTX 4 2
XC6VCX195T CXT 15600 124800 12160 344 640 10 10 15 600 16 GTX 1 2
XC6VLX240T LXT 18840 150720 14600 416 768 12 12 18 720 24 GTX 4 2
XC6VCX240T CXT 18840 150720 14600 416 768 12 12 18 600 16 GTX 1 2
XC6VLX365T LXT 28440 227520 16520 416 576 12 12 18 720 24 GTX 4 2
XC6VLX550T LXT 42960 343680 24800 632 864 18 18 30 1200 36 GTX 4 2
XC6VLX760 LX 59280 474240 33120 720 864 18 18 30 1200 - - -
XC6VSX315T SXT 24600 196800 20360 704 1344 12 12 18 720 24 GTX 4 2
XC6VSX475T SXT 37200 297600 30560 1064 2016 18 18 21 840 36 GTX 4 2
XC6VHX250T HXT 19680 157440 12160 504 576 12 12 8 320 48 GTX 4 4
XC6VHX255T HXT 19800 158400 12200 516 576 12 12 12 480 24 GTX + 24 GTH 2 2
XC6VHX380T HXT 29880 239040 18280 768 864 18 18 18 720 48 GTX + 24 GTH 4 4
XC6VHX565T HXT 44280 354240 25480 912 864 18 18 18 720 24 GTX + 24 GTH 4 4

Note: the I/O banks count does not include special bank 0, which contains only dedicated configuration I/O (no user I/O)

Note: the available user I/O, I/O bank, and multi-gigabit transceiver amount varies with chip packaging.

Note: Virtex-6 CLB grid is irregular and contains holes (for configuration center and PCI Express blocks), and so the CLB count is no longer a simple columns×rows multiplication

Note: The CXT devices use an identical die to the corresponding LXT devices, but with some disabled blocks and reduced performance (GTX transceivers have a speed range of 150 Mb/s to 3.75 Gb/s).

Spartan-6

The Spartan-6 devices are basically Spartan-3A DSP devices upgraded with some Virtex-6 technology. They are made of:[59]

  • CLBs (configurable logic blocks),[60] similar to Virtex-6, but with some changes:
    • SLICEs now come in three types: SLICEX, SLICEL, SLICEM; SLICEX is a bare-bones version of SLICEL (wide LUT multiplexers and carry chain have been removed, only LUTs and flip-flops remain)
    • every CLB contains two SLICEs: either one SLICEX + one SLICEL, or one SLICEX + one SLICEM; around 50% of the CLBs contain a SLICEM
  • 18kbit true dual port block RAMs,[61] similar to Spartan-3A DSP, but with additional capabilities:
    • the full 18kbit block RAM can be split into two 9kbit halves, with available configurations of 8192×1, 4096×2, 2048×4, 1024×9, 512×18
    • in split mode, the half block RAMs additionally support a simple dual port mode in 256×36 configuration
  • DSP48A1 blocks,[62] which are an upgraded version of the DSP48A blocks of Spartan-3A DSP devices
  • IOBs (I/O blocks, one per user pin):[63]
    • the electrical capabilities are similar to Spartan-3A (though with new I/O standards supported); there is no DCI support, but user can select an uncalibrated I/O impedance from several settings
    • Virtex-6-like ISERDES and OSERDES blocks are present (though with fewer capabilities than Virtex-6 devices), with associated fast I/O block buffers
    • the I/O bank arrangement is similar to Spartan-3A devices, but with a minor change: small devices have 4 banks (one for each device edge), while large devices have 6 banks (with the left and right edges split into two banks
  • MCBs (memory controller blocks),[64] hard memory controllers supporting DDR, DDR2, DDR3, and LPDDR memory
  • CMTs (clock management tiles),[65] each of which has:
    • two DCMs, similar to Spartan-3A DCMs, but with new clock generator mode and dynamic reconfiguration capabilities
    • one PLL, similar to Virtex-5 PLLs
  • 16 global clock buffers
  • multiple clock regions, with 16 regional clock buffers each, which can replace the corresponding global clock buffer output for that region
  • Miscellaneous configuration logic: like Spartan-3A, plus circuitry performing live configuration memory scanning with CRC error detection (but no correction)
  • (SXT devices only) GTP multi-gigabit transceivers[66] with speed ranges of 614 Mb/s to 810 Mb/s, 1.22 Gb/s to 1.62 Gb/s, and 2.45 Gb/s to 3.125 Gb/s, 8b/10b encoder and decoder, and parallel width of 8, 16, or 32 bits (10, 20, or 40 bits in 8b/10b bypass mode)
  • (SXT devices only) embedded PCI Express cores capable of Gen1.1 ×1 operation
Model Sub-family CLBs 6-LUTs (=CLBs×8) SLICEMs Block RAMs (18kbit each) DSP48A1 blocks DCMs PLLs Clock Regions I/O banks User I/Os (max) MCBs Gigabit transceivers (max) PCI Express Cores Notes
XC6SLX4 LX 300 2400 300 12 8 4 2 4 4 132 - - - uses the same die as XC6SLX9, with lots of disabled blocks
XC6SLX9 LX 715 5720 360 32 16 4 2 4 4 200 2 - -
XC6SLX16 LX 1139 9112 544 32 32 4 2 4 4 232 2 - -
XC6SLX25 LX 1879 15032 916 52 38 4 2 5 4 266 2 - - uses the same die as XC6SLX25T, with disabled transceivers
XC6SLX25T LXT 1879 15032 916 52 38 4 2 5 4 250 2 2 1
XC6SLX45 LX 3411 27288 1602 116 58 8 4 8 4 358 2 - - uses the same die as XC6SLX45T, with disabled transceivers
XC6SLX45T LXT 3411 27288 1602 116 58 8 4 8 4 296 2 4 1
XC6SLX75 LX 5831 46648 2768 172 132 12 6 12 6 408 4 - - uses the same die as XC6SLX75T, with disabled transceivers
XC6SLX75T LXT 5831 46648 2768 172 132 12 6 12 6 348 4 8 1
XC6SLX100 LX 7911 63288 3904 268 180 12 6 12 6 480 4 - - uses the same die as XC6SLX100T, with disabled transceivers
XC6SLX100T LXT 7911 63288 3904 268 180 12 6 12 6 498 4 8 1
XC6SLX150 LX 11519 92152 5420 268 180 12 6 12 6 576 4 - - uses the same die as XC6SLX150T, with disabled transceivers
XC6SLX150T LXT 11519 92152 5420 268 180 12 6 12 6 540 4 8 1

7 Series

The 7 series devices are made of:[67]

  • CLBs (configurable logic blocks), functionally identical to Virtex-6
  • 36kbit splittable true dual port block RAM, functionally identical to Virtex-6
  • DSP48E1 blocks, functionally identical to Virtex-6
  • IOBs (I/O blocks, one per user pin):[68] derived from Virtex-6, but with multiple changes:
    • the IOBs now come in two kinds
      • HR (high range) I/O, which once again supports I/O voltage up to 3.3V, but has no DCI support
      • HP (high performance) I/O, which supports I/O voltage up to 1.8V, with DCI support
    • the I/O banks now have 50 I/O pins each, as follows:
      • 24 differential I/O pairs, split into 4 "byte groups" of 6 I/O pairs (or 12 I/O pins)
      • 2 single I/O pins without differential pair
    • the CMTs (clock management tiles)[69] are now tightly coupled with I/O banks: there is one CMT for every I/O bank, and it contains:
      • one MMCM, similar to Virtex-6 MMCM
      • one PLL, which is a version of MMCM with less advanced functionality
      • four input and four output asynchronous FIFOs, designed for memory controller usage, but available for any application
      • undocumented phaser circuitry used only by the Xilinx memory controller IPs
  • global clock buffers (usually 32 of them, but some devices have only 16, and 3D devices have 32 for every die)
  • multiple clock regions, with 4 regional clock buffers per region
  • (not on the smallest Spartan devices) a single XADC analog-to-digital converter, which is an improved and renamed version of Virtex-6 system monitor
  • Miscellaneous configuration logic: like Virtex-6

Depending on exact device family, devices may also contain some special blocks:

  • GTP multi-gigabit transceivers,[70] with speed range of 500 Mb/s to 6.6 Gb/s and parallel width of 8 or 16 bits (10 or 20 in 8b/10b bypass mode)
  • GTX multi-gigabit transceivers,[71] with speed range of 500 Mb/s to 12.5 Gb/s and parallel width of 8, 16, or 32 bits (10, 20, or 40 in 8b/10b bypass mode)
  • GTH multi-gigabit transceivers, with speed range of 500 Mb/s to 13.1 Gb/s and parallel width of 8, 16, or 32 bits (10, 20, or 40 in 8b/10b bypass mode)
  • GTZ multi-gigabit transceivers, with speed range of up to 28.05 Gb/s and parallel width of up to 128 bits (160 in 8b/10b bypass mode). The GTZ transceivers, when present, reside on a separate die from the main FPGA. The documentation for GTZ transceivers is not publicly available, being restricted to members of Xilinx GTZ Lounge.
  • embedded PCI Express cores capable of Gen2 ×8 operation
  • embedded PCI Express cores capable of Gen3 ×8 operation
  • (Zynq-7000 devices) a PS (processing system) block,[72] containing a system on chip based on ARM Cortex-A9
Model Family CLBs 6-LUTs (=CLBs×8) SLICEMs Block RAMs (36kbit each) DSP48E1 blocks CMTs Clock Regions I/O banks (max) User I/Os (max) Gigabit transceivers (max) PCI Express Cores XADCs Processing System Notes
XC7S6 Spartan-7 469* 3752* 280* 5* 10* 2 2 2 HR 100 HR - - - - software-limitted version of XC7S15
XC7S15 Spartan-7 1000 8000 600 10 20 2 2 2 HR 100 HR - - - -
XC7S25 Spartan-7 1825 14600 1250 45 80 3 4 3 HR 150 HR - - 1 - XC7A25T with disabled transceivers
XC7S50 Spartan-7 4075 32600 2400 75 120 5 6 5 HR 250 HR - - 1 - XC7A50T with disabled transceivers
XC7S75 Spartan-7 6000* 48000* 3328* 90* 140* 8 8 8 HR 400 HR - - 1 - software-limitted version of XC7S100
XC7S100 Spartan-7 8000 64000 4400 120 160 8 8 8 HR 400 HR - - 1 -
XC7A12T Artix-7 1000* 8000* 684* 20* 40* 3 4 3 HR 150 HR 2 GTP 1 Gen2×4 1 - software-limitted version of XC7A25T
XC7A15T Artix-7 1300* 10400* 800* 25* 45* 5 6 5 HR 250 HR 4 GTP 1 Gen2×4 1 - software-limitted version of XC7A50T
XC7A25T Artix-7 1825 14600 1250 45 80 3 4 3 HR 150 HR 4 GTP 1 Gen2×4 1 -
XC7A35T Artix-7 2600* 20800* 1600* 50* 90* 5 6 5 HR 250 HR 4 GTP 1 Gen2×4 1 - software-limitted version of XC7A50T
XC7A50T Artix-7 4075 32600 2400 75 120 5 6 5 HR 250 HR 4 GTP 1 Gen2×4 1 -
XC7A75T Artix-7 5900* 47200* 3568* 105* 180* 6 8 6 HR 300 HR 8 GTP 1 Gen2×4 1 - software-limitted version of XC7A100T
XC7A100T Artix-7 7925 63400 4750 135 240 6 8 6 HR 300 HR 8 GTP 1 Gen2×4 1 -
XC7A200T Artix-7 16825 134600 11550 365 740 10 10 10 HR 500 HR 16 GTP 1 Gen2×4 1 -
XC7K70T Kintex-7 5125 41000 3350 135 240 6 8 4 HR + 2 HP 200 HR + 100 HP 8 GTX 1 Gen2×8 1 -
XC7K160T Kintex-7 12675 101400 8750 325 600 8 10 5 HR + 3 HP 250 HR + 150 HP 8 GTX 1 Gen2×8 1 -
XC7K325T Kintex-7 25475 203800 16000 445 840 10 14 7 HR + 3 HP 350 HR + 150 HP 16 GTX 1 Gen2×8 1 -
XC7K355T Kintex-7 27825 222600 20350 715 1440 6 12 6 HR 300 HR 24 GTX 1 Gen2×8 1 -
XC7K410T Kintex-7 31775 254200 22650 795 1540 10 14 7 HR + 3 HP 350 HR + 150 HP 16 GTX 1 Gen2×8 1 -
XC7K420T Kintex-7 32575* 260600* 23752* 835* 1680* 8 16 8 HR 400 HR 32 GTX 1 Gen2×8 1 - software-limitted version of XC7K480T
XC7K480T Kintex-7 37325 298600 27150 955 1920 8 16 8 HR 400 HR 32 GTX 1 Gen2×8 1 -
XC7V585T Virtex-7 45525 364200 27750 795 1260 18 18 3 HR + 15 HP 100 HR + 750 HP 36 GTX 3 Gen2×8 1 -
XC7V2000T Virtex-7 152700 1221600 86200 1292 2160 24 24 24 HP 1200 HP 36 GTX 4 Gen2×8 1 - 3D device, made of 4 identical FPGA die
XC7VX330T Virtex-7 25500 204000 17550 750 1120 14 14 1 HR + 13 HP 50 HR + 650 HP 28 GTH 2 Gen3×8 1 -
XC7VX415T Virtex-7 32200 257600 26100 880 2160 12 12 12 HP 600 HP 48 GTH 2 Gen3×8 1 -
XC7VX485T Virtex-7 37950 303600 32700 1030 2800 14 14 14 HP 700 HP 56 GTX 4 Gen2×8 1 -
XC7VX550T Virtex-7 43300* 346400* 34900* 1180* 2880* 20 20 20 HP 600 HP 80 GTH 2 Gen3×8 1 - software-limitted version of XC7VX690T
XC7VX690T Virtex-7 54150 433200 43550 1470 3600 20 20 20 HP 1000 HP 80 GTH 3 Gen3×8 1 -
XC7VX980T Virtex-7 76500 612000 55350 1500 3600 18 18 18 HP 900 HP 72 GTH 3 Gen3×8 1 -
XC7VX1140T Virtex-7 109400 875200 70800 1880 3360 24 24 24 HP 1100 HP 96 GTH 4 Gen3×8 1 - 3D device, made of 4 identical FPGA die
XC7VH580T Virtex-7 54700 437600 35400 940 1680 12 12 12 HP 600 HP 48 GTH + 8 GTZ 2 Gen3×8 1 - heterogenous 3D device, made of 2 FPGA die (identical to the XC7VX1140T FPGA die) and 1 GTZ die
XC7VH870T Virtex-7 82050 656400 53100 1410 2520 18 18 18 HP 300 HP 72 GTH + 16 GTZ 3 Gen3×8 1 - heterogenous 3D device, made of 3 FPGA die (identical to the XC7VX1140T FPGA die) and 2 GTZ die
XC7Z007S Zynq-7000 (Artix-7 FPGA fabric)[73] 1800* 14400* 50* 66* 2 4 2 HR 100 HR - - 1 single core software-limitted XC7Z010 with one ARM core disabled
XC7Z012S Zynq-7000 (Artix-7 FPGA fabric) 4300* 34400* 72* 120* 3 6 3 HR 150 HR 4 GTP 1 Gen2×4 1 single core software-limitted XC7Z015 with one ARM core disabled
XC7Z014S Zynq-7000 (Artix-7 FPGA fabric) 5075* 40600* 107* 170* 4 6 4 HR 200 HR - - 1 single core software-limitted XC7Z020 with one ARM core disabled
XC7Z010 Zynq-7000 (Artix-7 FPGA fabric) 2200 17600 1500 60 80 2 4 2 HR 100 HR - - 1 dual core
XC7Z015 Zynq-7000 (Artix-7 FPGA fabric) 5775 46200 3600 95 160 3 6 3 HR 150 HR 4 GTP 1 Gen2×4 1 dual core
XC7Z020 Zynq-7000 (Artix-7 FPGA fabric) 6650 53200 4350 140 220 4 6 4 HR 200 HR - - 1 dual core
XC7Z030 Zynq-7000 (Kintex-7 FPGA fabric) 9825 78600 6650 265 400 5 8 2 HR + 3 HP 100 HR + 150 HP 4 GTX 1 Gen2×4 1 dual core
XC7Z035 Zynq-7000 (Kintex-7 FPGA fabric) 21487.5* 171900* 500* 900 8 14 5 HR + 3 HP 212 HR + 150 HP 8 GTX 1 Gen2×8 1 dual core software-limitted version of XC7Z045
XC7Z045 Zynq-7000 (Kintex-7 FPGA fabric) 27325 218600 17600 545 900 8 14 5 HR + 3 HP 212 HR + 150 HP 8 GTX 1 Gen2×8 1 dual core
XC7Z100 Zynq-7000 (Kintex-7 FPGA fabric) 34675 277400 27050 755 2020 8 14 5 HR + 3 HP 250 HR + 150 HP 16 GTX 1 Gen2×8 1 dual core

Note: many 7 series devices are actually software-limitted versions of larger devices:[74] for example, XC7A35T is the exact same die as XC7A50T, with the same geometry and block count, but the Xilinx development tools artificially limit device usage to the limits in the table above. Such software-limitted devices have very different behavior from "full" devices when nearing full utilization: a design that would have utilized 90% of XC7A50T resources will most likely fail to route (or succeed with very suboptimal performance), since the place&route tool will have very little space to optimally arrange blocks and will likely run out of routing resources due to suboptimal placement. However, an XC7A35T design that utilizes even 100% of its resources will almost certainly route with no performance degradation, as it is far from the real hardware limits, and the placer has full freedom to utilize any subset of the available blocks as long as the total used CLB/DSP/block RAM count is within the allowed software limit. The software-enforced limits are marked with * in the above table.

Note: some Spartan-7 devices are identical to some Artix-7 devices, but with disabled transceivers. However, this is different from the above software-enforced usage limit: the transceivers cannot be used anyway, as their power and I/O pads are not bonded out to device pins in the packaging.

Note: the Artix-7 devices use the same PCI Express block as Kintex-7 devices, with Gen2×8 support, but they can only be used in at most Gen2×4 configuration due to GTP transceiver limitations.

Note: several devices have smaller max User I/Os count than the I/O bank count would imply. This means that the device is not available in any packaging that actually bonds out the complete set of pads.

UltraScale and UltraScale+

The UltraScale devices are made of:[75]

  • CLBs (configurable logic blocks), which are a modified version of the 7 Series CLB:
    • every CLB now contains exactly one SLICE, which can be a SLICEM or a SLICEL
    • every SLICE now contains 8 6-input LUTs, 16 flip-flops, a carry chain, and 3-level tree of wide LUT multiplexers, making it roughly equivalent to two 7 Series SLICEs (and retaining the rough logic capacity of a single CLB)
    • because of the higher wide LUT multiplexer tree, the LUTs within a SLICE can now be combined up to a single 9-input LUT
    • the available distributed RAM combinations within a SLICEM are now:
      • 32×16, 64×8, 128×4, 256×2, 512×1 single port RAM
      • 32×8, 64×4, 128×2, 256×1 dual port RAM
      • 32×4, 64×2, 128×1 quad port RAM
      • 32×2, 64×1 octal port RAM
      • 32×14, 64×7 simple dual port RAM
  • 36kbit splittable true dual block RAMs, with some minor upgrades compared to 7 Series
  • DSP48E2 blocks, with some minor upgrades compared to 7 Series DSP48E1 blocks
  • I/O banks with CMTs: with major changes from 7 Series[76]
    • banks still come in HR and HP kinds
    • each bank has 52 I/O pins: 24 differential pairs, and 4 unpaired pins
    • the bank is split into 4 byte groups, each made of 6 differential pairs and one unpaired pin
    • each byte group is further split into a lower nibble (with 3 differential pairs) and upper nibble (with 3 differential pairs and one unpaired pin)
    • the ISERDES/OSERDES blocks are replaced with BITSLICE blocks; there is one TX BITSLICE and one RX bitslice for every pin, plus an additional TX bitslice for every nibble that can control the tristate signal for all pins in a nibble
    • each bank has a CMT, with one MMCM and two PLLs
    • added MIPI D-PHY support
  • much more complex, distributed global clock network split into clock regions
  • system monitors, which is once again a renamed version of 7 Series XADC. There is one system monitor per FPGA die (ie. multi-die FPGAs have multiple system monitors).
  • Miscellaneous configuration logic
  • GTH multi-gigabit transceivers with speed up to 16.3 Gb/s and parallel width of 16, 32, or 64 bits (20, 40, or 80 bits in 8b/10b bypass mode)
  • (on some devices) GTY multi-gigabit transceivers with speed up to 30.5 Gb/s and parallel width of 16, 32, 64, or 128 bits (20, 40, 80, or 160 bits in 8b/10b bypass mode)
  • embedded PCI Express cores capable of Gen3 ×8 operation
  • (on some devices) 100 Gigabit Ethernet MAC
  • (on some devices) embedded Interlaken core

The UltraScale+ devices have a few differences:

  • HR banks no longer exist, being replaced with a new kind of I/O banks: HD (High Density) banks, which are very different to HR banks:
    • 24 pins (12 differential pairs) per bank
    • no CMT
    • no SERDES or BITSLICE blocks; the only logic available is simple flip-flops or DDR registers
  • upgraded MMCM and PLL
  • upgraded GTH transceivers
  • upgraded GTY transceivers with speed up to 32.75 Gb/s
  • some devices have GTM transceivers with speed up to 58.0 Gb/s (using PAM4 encoding) and parallel width of 16, 32, 64, or 128 bits (20, 40, 80, or 160 bits in 8b/10b bypass mode)
  • new PCI Express cores:
    • PCIE4 core capable of Gen3 ×16 or Gen4 ×8 operation
    • PCIE4C core, additionally capable of CCIX protocol
  • some devices have new UltraRAM blocks, which are true dual port 288kbit RAMs, in 4096×72 configuration

Zynq UltraScale+ devices are ARM Cortex-A53 based systems on chip sharing a die with an FPGA. The SoC part of the device is called a Processing System (PS). Each model of Zynq UltraScale+ MPSoC is available in up to 3 sub-models: CG, EG, and EV. The main differences among these sub-models are in the CPU and GPU configurations.[77] Zynq UltraScale+ RFSoC devices are available in DR sub-models, which have PS capabilities identical to MPSoC EG sub-models.

CG EG and DR EV
APU 2x Arm A53 4x Arm A53 4x Arm A53
RPU 2x Arm R5 2x Arm R5 2x Arm R5
GPU - Arm Mali-400MP2 Arm Mali-400MP2
VCU - - H.264/H.265

Zynq UltraScale+ devices have some additional blocks:

Model Family CLBs 6-LUTs (=CLBs×8) SLICEMs Block RAMs (36kbit each) Ultra RAMs (288kbit each) DSP48E2 blocks CMTs Clock Regions I/O banks (max) User I/Os (max) Gigabit transceivers (max) PCI Express Cores 100 Gigabit Ethernet MACs Intelaken Cores Others Notes
XCKU025 Kintex UltraScale 18180 145440 8460 360 - 1152 6 12 (4×3) 2 HR + 4 HP 104 HR + 208 HP 12 GTH 1 - - - cut (partial) version of XCKU040
XCKU035 Kintex UltraScale 25391* 203128* 540* - 1700* 10 20 (4×5) 2 HR + 8 HP 104 HR + 416 HP 16 GTH 2* - - - software-limitted version of XCKU040
XCKU040 Kintex UltraScale 30300 242400 14100 600 - 1920 10 20 (4×5) 2 HR + 8 HP 104 HR + 416 HP 20 GTH 3 - - -
XCKU060 Kintex UltraScale 41460 331680 18360 1080 - 2760 12 30 (6×5) 2 HR + 10 HP 104 HR + 520 HP 32 GTH 3 - - -
XCKU085 Kintex UltraScale 62190* 497520* 1620* - 4100* 22 54 (6×9) 4 HR + 18 HP 104 HR + 572 HP 56 GTH 4* - - - software-limitted version of XCKU115 with one partial die
XCKU095 Kintex UltraScale 67200 537600 9600 1680* - 768 16 40 (5×8) 1 HR + 15 HP 52 HR + 650 HP 32 GTH + 32 GTY 4 2* 2* - software-limitted version of XCVU095
XCKU115 Kintex UltraScale 82920 663360 36720 2160 - 5520 24 60 (6×10) 4 HR + 20 HP 156 HR + 676 HP 64 GTH 6 - - - a multi-die FPGA made of two XCKU060
XCVU065 Virtex UltraScale 44760 358080 9660 1260 - 600 10 30 (6×5) 1 HR + 9 HP 52 HR + 468 HP 20 GTH + 20 GTY 2 3 3 -
XCVU080 Virtex UltraScale 55714* 445712* 1421* - 672* 16 40 (5×8) 1 HR + 15 HP 52 HR + 780 HP 32 GTH + 32 GTY 4 4 6 - software-limitted version of XCVU095
XCVU095 Virtex UltraScale 67200 537600 9600 1728 - 768 16 40 (5×8) 1 HR + 15 HP 52 HR + 780 HP 32 GTH + 32 GTY 4 4 6 -
XCVU125 Virtex UltraScale 89520 716160 19320 2520 - 1200 20 60 (6×10) 2 HR + 18 HP 104 HR + 780 HP 40 GTH + 40 GTY 4 6 6 - a multi-die FPGA made of two XCVU065
XCVU160 Virtex UltraScale 115800* 926400* 3276* - 1560* 28 84 (6×14) 2 HR + 26 HP 52 HR + 650 HP 52 GTH + 52 GTY 4* 9 8 - software-limitted version of XCVU190 with one partial die
XCVU190 Virtex UltraScale 134280 1074240 28980 3780 - 1800 30 90 (6×15) 3 HR + 27 HP 52 HR + 650 HP 60 GTH + 60 GTY 6 9 9 - a multi-die FPGA made of three XCVU065
XCVU440 Virtex UltraScale 316620 2532960 57420 2520 - 2880 30 45 (9×5) 3 HR + 27 HP 52 HR + 1404 HP 48 GTH 6 3 - - a multi-die FPGA made of three dedicated die
XCAU10P Artix UltraScale+ 5500 44000 100 - 400 3 3 HP + 3 HD 156 HP + 72 HD 12 GTH 1 PCIE4C - - - not yet in production
XCAU15P Artix UltraScale+ 9720 77760 144 - 576 3 3 HP + 3 HD 156 HP + 72 HD 12 GTH 1 PCIE4C - - - not yet in production
XCAU20P Artix UltraScale+ 13625 109000 200 - 900 3 3 HP + 3 HD 156 HP + 72 HD 12 GTY 1 PCIE4 - - - not yet in production
XCAU25P Artix UltraScale+ 17625 141000 300 - 1200 4 4 HP + 4 HD 208 HP + 96 HD 12 GTY 1 PCIE4 - - - not yet in production
XCKU3P Kintex UltraScale+ 20340* 162720* 360* 48* 1368* 4 16 (4×4) 4 HP + 4 HD 208 HP + 96 HD 16 GTY 1 PCIE4 - - - software-limitted version of XCKU5P
XCKU5P Kintex UltraScale+ 27120 216960 12480 480 64 1824 4 16 (4×4) 4 HP + 4 HD 208 HP + 96 HD 16 GTY 1 PCIE4 1 - -
XCKU9P Kintex UltraScale+ 34260 274080 18000 912 - 2520 4 25 (4×7-3) 4 HP + 5 HD 208 HP + 96 HD 28 GTH - - - - same die as XCZU9*, with disabled PS
XCKU11P Kintex UltraScale+ 37320 298560 18540 600 80 2928 8 29 (4×8-3) 8 HP + 4 HD 416 HP + 96 HD 32 GTH + 20 GTY 4 PCIE4 2 1 - same die as XCZU11*, with disabled PS
XCKU13P Kintex UltraScale+ 42660 341280 23040 744 112 3528 4 25 (4×7-3) 4 HP + 5 HD 208 HP + 96 HD 28 GTH - - - - same die as XCZU15*, with disabled PS
XCKU15P Kintex UltraScale+ 65340 522720 20160 984 128 1968 11 41 (4×11-3) 11 HP + 4 HD 572 HP + 96 HD 44 GTH + 32 GTY 5 PCIE4 4 4 - same die as XCZU19*, with disabled PS
XCKU19P Kintex UltraScale+ 105300 842400 1728 288 1080 9 45 (5×9) 9 HP + 3 HD 468 HP + 72 HD 32 GTY 3 PCIE4C 1 - - partial version of XCVU23P
XCVU3P Virtex UltraScale+ 49260 394080 24660 720 320 2280 10 30 (6×5) 10 HP 520 HP 40 GTY 2 PCIE4 3 3 -
XCVU5P Virtex UltraScale+ 75072.125* 600577* 1024* 470* 3474* 20 60 (6×10) 20 HP 832 HP 80 GTY 4 PCIE4 4* 4* - software limited version of XCVU7P
XCVU7P Virtex UltraScale+ 98520 788160 49320 1440 640 4560 20 60 (6×10) 20 HP 832 HP 80 GTY 4 PCIE4 6 6 - a multi-die FPGA made of two XCVU3P FPGAs
XCVU9P, XCU200 Virtex UltraScale+ 147780 1182240 75120 2160 960 6840 30 90 (6×15) 30 HP 832 HP 120 GTY 6 PCIE4 9 9 - a multi-die FPGA made of three XCVU3P FPGAs;

XCU200 is the designation of the FPGA used on the Alveo U200 board, which is rebadged XCVU9P

XCVU11P Virtex UltraScale+ 162000 1296000 74160 2016 960 9216 12 96 (8×12) 12 HP 624 HP 96 GTY 3 PCIE4 9 6 - a multi-die FPGA made of three die
XCVU13P, XCU250 Virtex UltraScale+ 216000 1728000 98880 2688 1280 12288 16 128 (8×16) 16 HP 832 HP 128 GTY 4 PCIE4 12 8 - a multi-die FPGA made of four die (same base die as XCVU11P); XCU250 is the designation of the FPGA used on the Alveo U250 board, which is rebadged XCVU13P
XCVU19P Virtex UltraScale+ 510720 4085760 119520 2160 320 3840 40 180 (9×20) 40 HP + 4 HD 1976 HP + 96 HD 80 GTY 8 PCIE4C - - - a multi-die FPGA made of four die
XCVU23P, XCU26 Virtex UltraScale+ 128700 1029600 29040 2112 352 1320 11 55 (5×11) 11 HP + 3 HD 572 HP + 72 HD 34 GTY + 4 GTM 4 PCIE4C 2 - - XCU26 is the designation of the FPGA used on the Alveo SN1022 SmartNIC board, which is a rebadged XCVU23P
XCVU27P Virtex UltraScale+ 162000* 1296000* 74160* 2016* 960* 9216* 16 128 (8×16) 16 HP 676 HP 32 GTY + 48 GTM 1 PCIE4 15 8 - software-limitted version of XCVU29P
XCVU29P Virtex UltraScale+ 216000 1728000 98880 2688 1280 12288 16 128 (8×16) 16 HP 676 HP 32 GTY + 48 GTM 1 PCIE4 15 8 - a multi-die FPGA made of four die; one die is identical to the one used in XCVU11P, the other three contain the GTM transceivers
XCVU31P Virtex UltraScale+ HBM 54960 439680 25680 672 320 2880 4 32 (8×4) 4 HP 208 HP 32 GTY 4 PCIE4C 2 - HBM memory controller + 4GB HBM memory stack same die as XCVU33P, but with less HBM memory
XCVU33P Virtex UltraScale+ HBM 54960 439680 25680 672 320 2880 4 32 (8×4) 4 HP 208 HP 32 GTY 4 PCIE4C 2 - 2 HBM memory controllers + 2×4GB HBM memory stacks
XCVU35P, XCU50 Virtex UltraScale+ HBM 108960 871680 50400 1344 640 5952 8 64 (8×8) 8 HP 416 HP 64 GTY 1 PCIE4 + 4 PCIE4C 5 2 2 HBM memory controllers + 2×4GB HBM memory stacks a multi-die FPGA made of XCVU33P + one XCVU11P die; XCU50 is the designation of the FPGA used on the Alveo U50 board, which is rebadged XCVU35P
XCVU37P, XCU280 Virtex UltraScale+ HBM 162960 1303680 75120 2016 960 9024 12 96 (8×12) 12 HP 624 HP 96 GTY 2 PCIE4 + 4 PCIE4C 8 4 2 HBM memory controllers + 2×4GB HBM memory stacks a multi-die FPGA made of XCVU33P + two XCVU11P die; XCU280 is the designation of the FPGA used on the Alveo U280 board, which is rebadged XCVU37P
XCVU45P Virtex UltraScale+ HBM 108960 871680 50400 1344 640 5952 8 64 (8×8) 8 HP 416 HP 64 GTY 1 PCIE4 + 4 PCIE4C 5 2 2 HBM memory controllers + 2×8GB HBM memory stacks same as XCVU35P, but with more HBM memory
XCVU47P Virtex UltraScale+ HBM 162960 1303680 75120 2016 960 9024 12 96 (8×12) 12 HP 624 HP 96 GTY 2 PCIE4 + 4 PCIE4C 8 4 2 HBM memory controllers + 2×8GB HBM memory stacks same as XCVU37P, but with more HBM memory
XCVU57P Virtex UltraScale+ HBM 162960 1303680 75120 2016 960 9024 12 96 (8×12) 12 HP 624 HP 32 GTY + 32 GTM 4 PCIE4C 10 4 2 HBM memory controllers + 2×8GB HBM memory stacks same as XCVU47P, but with the XCVU11P die replaced with XCVU27P GTM-containing die
XCZU1CG, XCZU1EG Zynq UltraScale+ MPSoC 4680 37440 108 - 216 3 3 HP + 1 HD 156 HP + 24 HD - - - - Processing System not yet in production
XCZU2CG, XCZU2EG Zynq UltraScale+ MPSoC 5904* 47232* 150* - 240* 3 6 (2×3) 3 HP + 4 HD 156 HP + 96 HD - - - - Processing System software-limitted XCZU3
XCZU3CG, XCZU3EG Zynq UltraScale+ MPSoC 8820 70560 3600 216 - 360 3 6 (2×3) 3 HP + 4 HD 156 HP + 96 HD - - - - Processing System
XCZU4CG, XCZU4EG, XCZU4EV Zynq UltraScale+ MPSoC 10980* 87840* 128* 48* 728* 4 12 (3×4) 4 HP + 4 HD 156 HP + 96 HD 16 GTH 2 PCIE4 - - Processing System, VCU software-limitted XCZU5
XCZU5CG, XCZU5EG, XCZU5EV, XCK26 Zynq UltraScale+ MPSoC 14640 117120 7200 144 64 1248 4 12 (3×4) 4 HP + 4 HD 156 HP + 96 HD 16 GTH 2 PCIE4 - - Processing System, VCU XCK26 is the designation of the device on the Kria K26 system on module, which is a rebadged XCZU5EV device
XCZU6CG, XCZU6EG Zynq UltraScale+ MPSoC 26825.5* 214604* 714* - 1973* 4 25 (4×7-3) 4 HP + 5 HD 208 HP + 120 HD 24 GTH - - - Processing System software-limitted XCZU9
XCZU7CG, XCZU7EG, XCZU7EV, XCU30 Zynq UltraScale+ MPSoC 28800 230400 12720 312 96 1728 8 20 (4×6-4) 8 HP + 4 HD 416 HP + 48 HD 24 GTH 2 PCIE4 - - Processing System, VCU XCU30 is the designation of the devices on the Alveo U30 board, which are rebadged XCZU7EV devices
XCZU9CG, XCZU9EG Zynq UltraScale+ MPSoC 34260 274080 18000 912 - 2520 4 25 (4×7-3) 4 HP + 5 HD 208 HP + 120 HD 24 GTH - - - Processing System
XCZU11EG Zynq UltraScale+ MPSoC 37320 298560 18540 600 80 2928 8 29 (4×8-3) 8 HP + 4 HD 416 HP + 96 HD 32 GTH + 16 GTY 4 PCIE4 2 1 Processing System
XCZU15EG Zynq UltraScale+ MPSoC 42660 341280 23040 744 112 3528 4 25 (4×7-3) 4 HP + 5 HD 208 HP + 120 HD 24 GTH - - - Processing System
XCZU17EG Zynq UltraScale+ MPSoC 52925.375* 423403* 796* 102* 1590* 11 41 (4×11-3) 11 HP + 4 HD 572 HP + 96 HD 44 GTH + 28 GTY 4* PCIE4 2* 2* Processing System software-limitted XCZU19
XCZU19EG, XCU25 Zynq UltraScale+ MPSoC 65340 522720 20160 984 128 1968 11 41 (4×11-3) 11 HP + 4 HD 572 HP + 96 HD 44 GTH + 28 GTY 5 PCIE4 4 4 Processing System XCU25 is the designation of the device on the Alveo U25 board, which is a rebadged XCZU19EG device
XCZU21DR Zynq UltraScale+ RFSoC 53160 425280 26700 1080 80 4272 8 45 (6×8-3) 8 HP + 6 HD 208 HP + 72 HD 16 GTY 2 PCIE4 2 1 Processing System,

8 SD-FEC cores

same die as XCZU28DR
XCZU25DR Zynq UltraScale+ RFSoC 38761* 310088* 19561* 792* 48* 3145* 6 33 (6×6-3) 6 HP + 4 HD 299 HP + 48 HD 8 GTY 1 PCIE4 1 1 Processing System,

8×4GSPS RF-ADC, 8×6.5GSPS RF-DAC

partial XCZU28DR die
XCZU27DR Zynq UltraScale+ RFSoC 53160 425280 26700 1080 80 4272 8 45 (6×8-3) 8 HP + 6 HD 299 HP + 48 HD 16 GTY 2 PCIE4 2 1 Processing System,

8×4GSPS RF-ADC, 8×6.5GSPS RF-DAC

same die as XCZU28DR
XCZU28DR Zynq UltraScale+ RFSoC 53160 425280 26700 1080 80 4272 8 45 (6×8-3) 8 HP + 6 HD 299 HP + 48 HD 16 GTY 2 PCIE4 2 1 Processing System,

8×4GSPS RF-ADC, 8×6.5GSPS RF-DAC,

8 SD-FEC cores

XCZU29DR Zynq UltraScale+ RFSoC 53160 425280 26700 1080 80 4272 8 45 (6×8-3) 8 HP + 6 HD 312 HP + 96 HD 16 GTY 2 PCIE4 2 1 Processing System,

16×2GSPS RF-ADC, 16×6.5GSPS RF-DAC

same die as XCZU28DR
XCZU39DR Zynq UltraScale+ RFSoC 53160 425280 26700 1080 80 4272 8 45 (6×8-3) 8 HP + 6 HD 312 HP + 96 HD 16 GTY 2 PCIE4 2 1 Processing System,

16×2.2GSPS RF-ADC, 16×6.5GSPS RF-DAC

same die as XCZU28DR
XCZU42DR Zynq UltraScale+ RFSoC 27960 223680 648 160 1872 5 5 HP + 1 HD 128 HP + 24 HD 8 GTY - - - Processing System,

2×5GSPS RF-ADC,

8×2.5GSPS RF-ADC,

8×10GSPS RF-DAC

XCZU43DR Zynq UltraScale+ RFSoC 53160 425280 26700 1080 80 4272 8 45 (6×8-3) 8 HP + 6 HD 299 HP + 48 HD 16 GTY 2 PCIE4C 2 1 Processing System,

4×5GSPS RF-ADC,

4×10GSPS RF-DAC

same die as XCZU48DR
XCZU46DR Zynq UltraScale+ RFSoC 53160 425280 26700 1080 80 4272 8 45 (6×8-3) 8 HP + 6 HD 312 HP + 48 HD 16 GTY 2 PCIE4C 2 1 Processing System,

4×5GSPS RF-ADC,

8×2.5GSPS RF-ADC

12×10GSPS RF-DAC,

8 SD-FEC cores

same die as XCZU48DR
XCZU47DR Zynq UltraScale+ RFSoC 53160 425280 26700 1080 80 4272 8 45 (6×8-3) 8 HP + 6 HD 299 HP + 48 HD 16 GTY 2 PCIE4C 2 1 Processing System,

8×5GSPS RF-ADC,

8×10GSPS RF-DAC

same die as XCZU48DR
XCZU48DR Zynq UltraScale+ RFSoC 53160 425280 26700 1080 80 4272 8 45 (6×8-3) 8 HP + 6 HD 299 HP + 48 HD 16 GTY 2 PCIE4C 2 1 Processing System,

8×5GSPS RF-ADC,

8×10GSPS RF-DAC,

8 SD-FEC cores

XCZU49DR Zynq UltraScale+ RFSoC 53160 425280 26700 1080 80 4272 8 45 (6×8-3) 8 HP + 6 HD 312 HP + 96 HD 16 GTY 2 PCIE4C 2 1 Processing System,

16×2.5GSPS RF-ADC,

16×10GSPS RF-DAC

same die as XCZU48DR

Note: the clock region grid is irregular on some UltraScale+ devices because of a hole in bottom for the Processing System (and possibly the VCU).

Versal

In 2018, Xilinx announced a product line called Versal.[78] Versal chips will contain CPU, GPU, DSP, and FPGA components. Versal will be fabricated using 7nm process technology. Xilinx has stated that Versal products will be available in the second half of 2019.[79]

The Versal devices are made of:[80]

  • PMC (Platform Management Controller), a MicroBlaze-based processor block responsible for booting the device and monitoring its operations
  • PS (Processing System), an ARM system on a chip block with dual core Cortex-A72 (APU) and dual-core Cortex-R5F (RPU)
  • (on some devices) CPM, a hard PCI Express block with CCIX support; comes in Gen4 and Gen5 version
  • (on some devices) XRAM, a single 32Mbit block of static RAM
  • a NoC (Network on Chip) spanning the device, with AXI4 interface blocks, connecting the PS, the CPM, the FPGA, the DDRMC cores, and the AI cores together
  • one or more DDRMC (DDR memory controller) blocks
  • XPIO I/O banks, which are the successor to UltraScale+ HP I/O banks; in a departure from previous devices, the XPIO banks are considered to be outside the FPGA part, and some XPIO banks can only be used by the DDRMC blocks (without FPGA connectivity)
  • GTY transceivers, which can be used by the FPGA or by the CPM
  • GTYP transceivers, which are a minor improvement of GTY transceivers
  • GTM transceivers
  • the FPGA fabric with:
    • configurable logic blocks (CLBs), which are quite different to previous architectures
      • a CLB is made of 4 SLICEs: 2 SLICELs and 2 SLICEMs
      • each SLICE still contains 8 6-input LUTs, each fracturable into two 5-input LUTs with shared inputs
      • each slice still contains 16 flip-flops, two for each LUT
      • there are no more wide LUT multiplexers
      • the carry chain has been replaced with new carry and cascade logic
      • the distributed RAM configurations are different
    • 36kbit true dual port block RAMs, with some changes from UltraScale+
    • 288kbit UltraRAM blocks, with some changes from UltraScale+
    • DSP58 blocks, which replace the old DSP48* blocks; two adjacent DSP58 blocks can be combined into a single DSP58_CPLX block, performing complex arithmetic
    • HD I/O blocks, similar to UltraScale+
      • now with 11 differential pairs (22 pins) per block
    • NoC master access ports
    • NoC slave access ports
    • hard IP blocks:
      • PCI Express Gen4 and Gen5 cores
      • MRMAC (Multirate Ethernet MAC), usable in 1×100Gbit, 2×50Gbit, 1×40Gbit, 4×25Gbit, 4×10Gbit configurations
      • DCMAC (600G Channelized Multirate Ethernet Subsystem), usable in 1×400Gbit, 3×200Gbit, 6×100Gbit configurations
      • 600Gbit Interlaken block, usable in 12×56.42Gbit, 24×28.21Gbit, or 24×12.5Gbit configurations
      • 400Gbit HSC (High-Speed Crypto) Engine, usable in 1×400Gbit, 2×200Gbit, or 4×100Gbit configurations
  • (on some devices) AI Engines, vector processor cores meant for machine learning usage
Model Family SLICEs 6-LUTs (=SLICEs×8) Block RAMs (36kbit each) Ultra RAMs (288kbit each) DSP58 blocks DDRMC blocks XPIO banks HDIO banks NoC master/slave ports Transceivers PCI Express blocks Ethernet MACs Interlaken blocks HSC blocks AI Engines Other Notes
XCVC1352 Versal AI Core 30848 246784 441 209 928 2 7 2 10 8 GTYP 1 Gen4 1 MRMAC - - 128 XRAM not yet in production
XCVC1502 Versal AI Core 45568 364544 547 215 1312 2 7 2 14 44 GTY 4 Gen4 4 MRMAC - - 248 CPM Gen4 not yet in production
XCVC1702 Versal AI Core 60032 480256 826 402 1696 2 7 2 18 24 GTYP 1 Gen4 3 MRMAC - - 320 XRAM not yet in production
XCVC1802 Versal AI Core 90625* 725000* 800* 325* 1600* 4 12 2 28 44 GTY 4 Gen4 4 MRMAC - - 300 (50×6) CPM Gen4 software-limitted version of XCVC1902
XCVC1902 Versal AI Core 112480 899840 967 463 1968 4 12 2 28 44 GTY 4 Gen4 4 MRMAC - - 400 (50×8) CPM Gen4
XCVM1102 Versal Prime 18784 150272 155 155 464 1 4 1 5 8 GTYP 1 Gen4 1 MRMAC - - - - not yet in production
XCVM1302 Versal Prime 39616 316928 502 178 832 2 8 1 9 24 GTY 2 Gen4 2 MRMAC - - - CPM Gen4 not yet in production
XCVM1402 Versal Prime 70720 565760 1150 286 1696 4 12 1 18 24 GTY 2 Gen4 2 MRMAC - - - CPM Gen4 not yet in production
XCVM1502 Versal Prime 45568 364544 547 215 1312 2 7 2 14 44 GTY 4 Gen4 4 MRMAC - - - CPM Gen4 not yet in production
XCVM1802 Versal Prime 112480 899840 967 463 1968 4 12 2 28 44 GTY 4 Gen4 4 MRMAC - - - CPM Gen4 XCVC1902 with AI Engines disabled
XCVM2202 Versal Prime 65088 520704 600 264 1312 3 9 2 21 32 GTYP 2 Gen5 2 MRMAC - - - CPM Gen5 not yet in production
XCVM2302 Versal Prime 89984 719872 1405 453 1904 3 9 2 30 8 GTYP + 40 GTM 2 Gen5 6 MRMAC - - - - not yet in production
XCVM2502 Versal Prime 112528 900224 1341 677 3984 4 12 - 28 28 GTYP + 16 GTM 2 Gen5 2 MRMAC - - - CPM Gen5 not yet in production
XCVM2902 Versal Prime 127616 1020928 1981 645 2672 3 7 2 42 8 GTYP + 40 GTM 2 Gen5 6 MRMAC - - - - not yet in production
XCVP1102 Versal Premium 89984 719872 1405 453 1904 3 9 2 30 8 GTYP + 64 GTM 2 Gen5 6 MRMAC + 4 DCMAC 2 3 - - not yet in production
XCVP1202 Versal Premium 112528 900224 1341 677 3984 4 13 - 28 28 GTYP + 20 GTM 2 Gen5 2 MRMAC + 1 DCMAC - 1 - 2 CPM Gen5 not yet in production
XCVP1402 Versal Premium 127616 1020928 1981 645 2672 3 9 2 42 8 GTYP + 96 GTM 2 Gen5 6 MRMAC + 8 DCMAC 2 5 - - not yet in production
XCVP1502 Versal Premium 215056 1720448 2541 1301 7440 4 13 - 52 28 GTYP + 60 GTM 2 Gen5 4 MRMAC + 3 DCMAC 1 2 - 2 CPM Gen5 not yet in production
XCVP1552 Versal Premium 219248 1753984 2541 1301 7392 4 13 - 52 68 GTYP + 20 GTM 8 Gen5 4 MRMAC + 1 DCMAC - 2 - 2 CPM Gen5 not yet in production
XCVP1702 Versal Premium 317584 2540672 3741 1925 10896 4 13 - 76 28 GTYP + 100 GTM 2 Gen5 6 MRMAC + 5 DCMAC 2 3 - 2 CPM Gen5 not yet in production
XCVP1802 Versal Premium 420112 3360896 4941 2549 14352 4 12 - 100 28 GTYP + 140 GTM 2 Gen5 8 MRMAC + 7 DCMAC 3 4 - 2 CPM Gen5 not yet in production

FPGAs without integrated CPUs[81]

Artix

Family Launch Process Logic cells Block RAM DSP slices MGT PCIe blocks Mem Intf BW IO pins VCCINT
nm Count (K) TITO (ns) TCKO (ns) Total (Mb) FMAX (MHz) Count Total GMAC/s FMAX (MHz) Type Count Gbps Total Gbps Type Count Type Gbps
Artix-7 2010 28 nm 16-215 0.94 0.4 0.9-13 509 45-740 929 628 GTP 0-16 6.6 211 x4 Gen2 1 DDR3 1066 106-500 1.00

Kintex

Family Launch Process Logic cells Block RAM UltraRAM DSP slices MGT PCIe blocks Mem Intf BW IO pins VCCINT
nm Count (K) TITO (ns) TCKO (ns) Total (Mb) FMAX (MHz) Total (Mb) FMAX (MHz) Count Total GMAC/s FMAX (MHz) Type Count Gbps Total Gbps Type Count Type Gbps
Kintex-7 2010 28 nm 66-478 0.58 0.26 5-34 601 240-1920 2845 741 GTX 4-32 12.5 800 x8 Gen2 1 DDR3 1866 285-500 1.00
Kintex UltraScale 2013[82] 20 nm 318-1451 12.7-75.9 660 768-5520 8180 741 GTH, GTY 12-64 16.3 2086 x8 Gen3 1-6 DDR3 2400 312-832 0.95
Kintex UltraScale+ 2015[83] 16 nm 356-1143 12.7-34.6 825 0-36 650 1368-3528 6287 891 GTH, GTY 16-76 32.75 3268 x16 Gen3 0-5 DDR4 2666 280-668 0.85

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