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This generationallist of Intel processors attempts to present all ofIntel'sprocessors from the4-bit4004 (1971) to the present high-end offerings. Concise technical data is given for each product.

Released on October 24, 2024. It follows on from Meteor Lake which saw Intel move from monolithic silicon to a disaggregated MCM design.Meteor Lake was limited to a mobile release whileArrow Lake includes desktop processors and mobile processors.

Socket LGA 1851

Arrow Lake-U uses refreshedMeteor Lake silicon fabricated on theIntel 3 node.

An iterative refresh of Raptor Lake-S desktop processors, called the 14th generation of Intel Core, was launched on October 17, 2023.^[1][2]

Socket LGA 1700

CPUs inbold below feature ECC memory support when paired with a motherboard based on the W680 chipset according to each respective Intel Ark product page.

An iterative refresh of Raptor Lake-HX mobile processors, called the 14th generation of Intel Core, was launched on Jan 9, 2024^[3]

155H, 165H, and 185H support P-core Turbo Boost 3.0 running at the same frequency as Turbo Boost 2.0.

The integrated GPU is branded as "Intel Graphics" but still use the same GPU microarchitecture as "Intel Arc Graphics" on the H series models.

All models support DDR5 memory except 134U and 164U.

These Raptor Lake–based processors are branded as "Core Series 1" vs. theMeteor Lake–based ones which are branded "Core Ultra Series 1."

These Raptor Lake–based processors are branded as "Core Series 2", Unlike Arrow Lake's "Core Ultra Series 2".

All processors are listed in chronological order.

First commercially availablemicroprocessor (single-chip IC processor)

• Introduced November 15, 1971
• Clock rate 740kHz^[b]
• 0.07 MIPS
• Bus width: 4 bits (five-way multiplexed address/data due to limited pins)
• PMOS
• 2,300 transistors at 10 μm
• Addressable memory 640 bytes
• Program memory 4 KB (4096 B)
• Originally designed to be used inBusicom calculator

MCS-4 family:

• 4004 –CPU
• 4001 – 256 byteROM & 4-bit Port
• 4002 – 320 bitRAM & 4-bit Port
• 4003 – 10-bit Shift Register
• 4008 – Memory+I/O Interface
• 4009 – Memory+I/O Interface
• 4211 – General Purpose Byte I/O Port
• 4265 – Programmable General Purpose I/O Device
• 4269 – Programmable Keyboard Display Device
• 4289 – Standard Memory Interface for MCS-4/40
• 4801 – 5.185 MHz Clock Generator Crystal for 4004/4201A or 4040/4201A

• Introduced in 1974 by Intel
• Clock speed was 740 kHz (same as the 4004 microprocessor)
• 3,000 transistors
• Interrupt features were available
• Programmable memory size: 8 KB (8192 B)
• 640 bytes of data memory
• 24-pin DIP

• Introduced April 1, 1972
• Clock rate 500 kHz (8008-1: 800 kHz)
• 0.05 MIPS
• Bus width: 8 bits (triple-multiplexed address/data due to limited pins)
• Enhancement loadPMOS logic
• 3,500 transistors at 10 μm
• Addressable memory 16 KB
• Typical in early 8-bit microcomputers, dumb terminals, general calculators, bottling machines
• Developed in tandem with 4004
• Originally intended for use in theDatapoint 2200 microcomputer
• Key volume deployment in Texas Instruments 742 microcomputer in >3,000 Ford dealerships

• Introduced April 1, 1974
• Clock rate 2 MHz (very rare 8080B: 3 MHz)
• 0.29 MIPS^[8]
• Data bus width: 8 bits, address bus: 16 bits
• Enhancement loadNMOS logic
• 4,500 transistors at 6 μm
• Assembly language downward compatible with 8008
• Addressable memory 64 KB (64 × 1024 B)
• Up to 10× the performance of the 8008
• Used in theAltair 8800,traffic light controller,cruise missile
• Required two support chips versus 20 for the 8008

• Introduced March 1976
• Clock rate 3 MHz^[9]
• 0.37 MIPS
• Data bus width: 8 bits, address bus: 16 bits, multiplexed
• Depletion loadNMOS logic
• 6,500 transistors at3 μm
• Downwardbinary compatible with the 8080
• Used inToledo scales. Also used as a computer peripheral controller – modems, hard disks, printers, etc.
• CMOS 80C85 inMars Sojourner,Radio Shack Model 100 portable

They are ICs with CPU, RAM, ROM (or PROM or EPROM), I/O Ports, Timers & Interrupts

• SingleaccumulatorHarvard architecture

MCS-48 family:

• 8020 – Single-Component 8-bit Microcontroller, 1 KB ROM, 64 Byte RAM, 13 I/O ports
• 8021 – Single-Component 8-bit Microcontroller, 1 KB ROM, 64 Byte RAM, 21 I/O ports
• 8022 – Single-Component 8-bit Microcontroller, 2 KB ROM, 64 Byte RAM with on-chip A/D Converter
• 8035 – 8-bit Microcontroller, 64 Byte RAM
• 8039 – 8-bit Microcontroller, 128 Byte RAM
• 8040 – 8-bit Microcontroller, 256 Byte RAM
• 8048 – Single-Component 8-bit Microcontroller, 1 KB ROM, 64 byte RAM, 27 I/O ports, 0.73 MIPS @ 11 MHz
• 8049 – Single-Component 8-bit Microcontroller, 2 KB ROM, 128 byte RAM, 27 I/O ports,
• 8050 – Single-Component 8-bit Microcontroller, 4 KB ROM, 256 byte RAM, 27 I/O ports,
• 8748 – Single-Component 8-bit Microcontroller, 1 KB EPROM, 64 byte RAM, 27 I/O ports,
• 8749 – Single-Component 8-bit Microcontroller, 2 KB EPROM, 128 byte RAM, 27 I/O ports,
• 87P50 – 8-bit Microcontroller, ext. ROM socket (2758/2716/2732), 256 byte RAM, 27 I/O ports
• 8648 – Single-Component 8-bit Microcontroller, 1 KBOTP EPROM, 64 byte RAM, 27 I/O ports
• 8041 – Universal Peripheral Interface 8-bit Slave Microcontroller, 1 KB ROM, 64 byte RAM
• 8041AH – Universal Peripheral Interface 8-bit Slave Microcontroller, 1 KB ROM, 128 byte RAM
• 8641 – Universal Peripheral Interface 8-bit Slave Microcontroller ?
• 8741 – Universal Peripheral Interface 8-bit Slave Microcontroller, 1 KB EPROM, 64 byte RAM
• 8741AH – Universal Peripheral Interface 8-bit Slave Microcontroller, 1 KB EPROM, 128 byte RAM
• 8042 – Universal Peripheral Interface 8-bit Slave Microcontroller, 2 KB ROM, 256 byte RAM
• 8742 – Universal Peripheral Interface 8-bit Slave Microcontroller, 2 KB EPROM, 128 byte RAM
• 8742AH – Universal Peripheral Interface 8-bit Slave Microcontroller, 2 KB OTP EPROM, 256 byte RAM

• SingleaccumulatorHarvard architecture

MCS-51 family:

• 8031 – 8-bit Control-Oriented Microcontroller
• 8032 – 8-bit Control-Oriented Microcontroller
• 8044 – High Performance 8-bit Microcontroller
• 8344 – High Performance 8-bit Microcontroller
• 8744 – High Performance 8-bit Microcontroller
• 8051 – 8-bit Control-Oriented Microcontroller
• 8052 – 8-bit Control-Oriented Microcontroller
• 8054 – 8-bit Control-Oriented Microcontroller
• 8058 – 8-bit Control-Oriented Microcontroller
• 8351 – 8-bit Control-Oriented Microcontroller
• 8352 – 8-bit Control-Oriented Microcontroller
• 8354 – 8-bit Control-Oriented Microcontroller
• 8358 – 8-bit Control-Oriented Microcontroller
• 8751 – 8-bit Control-Oriented Microcontroller
• 8752 – 8-bit Control-Oriented Microcontroller
• 8754 – 8-bit Control-Oriented Microcontroller
• 8758 – 8-bit Control-Oriented Microcontroller

• SingleaccumulatorHarvard architecture

MCS-151 family:

• 80151 – High Performance 8-bit Control-Oriented Microcontroller
• 83151 – High Performance 8-bit Control-Oriented Microcontroller
• 87151 – High Performance 8-bit Control-Oriented Microcontroller
• 80152 – High Performance 8-bit Control-Oriented Microcontroller
• 83152 – High Performance 8-bit Control-Oriented Microcontroller

• SingleaccumulatorHarvard architecture

MCS-251 family:

• 80251 – 8/16/32-bit Microcontroller
• 80252 – 8/16/32-bit Microcontroller
• 80452 – 8/16/32-bit Microcontroller
• 83251 – 8/16/32-bit Microcontroller
• 87251 – 8/16/32-bit Microcontroller
• 87253 – 8/16/32-bit Microcontroller

• 8061 – 16-bit Microcontroller (parent of MCS-96 family ROMless With A/D, most sold to Ford)
• 8094 –16-bit Microcontroller (48-Pin ROMLess Without A/D)
• 8095 – 16-bit Microcontroller (48-Pin ROMLess With A/D)
• 8096 – 16-bit Microcontroller (68-Pin ROMLess Without A/D)
• 8097 – 16-bit Microcontroller (68-Pin ROMLess With A/D)
• 8394 – 16-bit Microcontroller (48-Pin With ROM Without A/D)
• 8395 – 16-bit Microcontroller (48-Pin With ROM With A/D)
• 8396 – 16-bit Microcontroller (68-Pin With ROM Without A/D)
• 8397 – 16-bit Microcontroller (68-Pin With ROM With A/D)
• 8794 – 16-bit Microcontroller (48-Pin With EROM Without A/D)
• 8795 – 16-bit Microcontroller (48-Pin With EROM With A/D)
• 8796 – 16-bit Microcontroller (68-Pin With EROM Without A/D)
• 8797 – 16-bit Microcontroller (68-Pin With EROM With A/D)
• 8098 – 16-bit Microcontroller
• 8398 – 16-bit Microcontroller
• 8798 – 16-bit Microcontroller
• 80196 – 16-bit Microcontroller
• 83196 – 16-bit Microcontroller
• 87196 – 16-bit Microcontroller
• 80296 – 16-bit Microcontroller

Introduced in the third quarter of 1974, thesebit-slicing components usedbipolar Schottky transistors. Each component implemented two bits of aprocessor function; packages could be interconnected to build a processor with any desired word length.

Members of the 3000 family:

• 3001 – Microcontrol Unit
• 3002 – 2-bit Arithmetic Logic Unit slice^[10]
• 3003 – Look-ahead Carry Generator
• 3205 – High-performance 1 of 8 Binary Decoder
• 3207 – Quad Bipolar-to-MOS Level Shifter and Driver
• 3208 – Hex Sense Amp and Latch for MOS Memories
• 3210 – TTL-to-MOS Level Shifter and High Voltage Clock Driver
• 3211 – ECL-to-MOS Level Shifter and High Voltage Clock Driver
• 3212 – Multimode Latch Buffer
• 3214 – Interrupt Control Unit
• 3216 – Parallel, Inverting Bi-Directional Bus Driver
• 3222 – Refresh Controller for 4K (4096 B) NMOS DRAMs
• 3226 – Parallel, Inverting Bi-Directional Bus Driver
• 3232 – Address Multiplexer and Refresh Counter for 4K DRAMs
• 3242 – Address Multiplexer and Refresh Counter for 16K (16 × 1024 B) DRAMs
• 3245 – Quad Bipolar TTL-to-MOS Level Shifter and Driver for 4K
• 3246 – Quad Bipolar ECL-to-MOS Level Shifter and Driver for 4K
• 3404 – High-performance 6-bit Latch
• 3408 – Hex Sense Amp and Latch for MOS Memories
• 3505 – Next generation processor

Bus width 2n bits data/address (depending on numbern of slices used)

• Introduced June 8, 1978
• Clock rates:
  • 5 MHz, 0.33 MIPS^[9]
  • 8 MHz, 0.66 MIPS
  • 10 MHz, 0.75 MIPS
• The memory is divided into odd and even banks. It accesses both banks concurrently to read 16 bits of data in one memory cycle
• Data bus width: 16 bits, address bus: 20 bits, multiplexed
• 29,000 transistors at 3 μm
• Addressable memory: 1 megabyte (1024² B)
• Up to 10× the performance of 8080
• First used in the Compaq Deskpro IBM PC-compatible computers. Later used in portable computing, and in theIBMPS/2Model 25 andModel 30. Also used in theAT&T PC6300 / Olivetti M24, a popular IBM PC-compatible (predating the IBM PS/2 line) and the WANG PC.
• Usedsegment registers to access more than 64 KB of data at once.
• The first x86 CPU
• Later renamed the iAPX 86^[11]

• Introduced June 1, 1979
• Clock rates:
  • 4.77 MHz, 0.33 MIPS
  • 8 MHz, 0.66 MIPS^[9]
• 16-bit internal architecture
• External data bus width: 8 bits, address bus: 20 bits, lower 8 bits multiplexed
• 29,000 transistors at 3 μm
• Addressable memory: 1 megabyte
• Identical to 8086 except for its 8-bit external bus (hence an8 instead of a6 at the end); identical Execution Unit (EU), different Bus Interface Unit (BIU)^[11]
• Used inIBM PC and PC-XT and compatibles
• Later renamed the iAPX 88^[11]

• Introduced 1982
• Clock rates
  • 6 MHz, > 1 MIPS
• 55,000 transistors
• Included two timers, aDMA controller, and aninterrupt controller on the chip in addition to the processor (these were at fixed addresses which differed from the IBM PC, although it was used by several PC compatible vendors such as Australian company Cleveland)
• Added a few opcodes and exceptions to the 8086 design, otherwise identical instruction set to 8086 and 8088
  • BOUND, ENTER, LEAVE
  • INS, OUTS
  • IMUL imm, PUSH imm, PUSHA, POPA
  • RCL/RCR/ROL/ROR/SHL/SHR/SAL/SAR reg, imm
• Address calculation and shift operations are faster than 8086
• Used mostly in embedded applications – controllers, point-of-sale systems, terminals, and the like
• Used in several non-PC compatible computers includingRM Nimbus,Tandy 2000, and CP/M 86 Televideo PM16 server
• Later renamed to iAPX 186

• A version of the 80186 with an 8-bit external data bus
• Later renamed the iAPX 188

• Introduced February 1, 1982
• Clock rates:
  • 6 MHz, 0.9 MIPS
  • 8 MHz, 10 MHz, 1.5 MIPS
  • 12.5 MHz, 2.66 MIPS
  • 16 MHz, 20 MHz and 25 MHz available.
• Data bus width: 16 bits, address bus: 24 bits
• Included memory protection hardware to support multitasking operating systems with per-process address space.
• 134,000 transistors at1.5 μm
• Addressable memory 16 MB
• Added protected-mode features to 8086 with essentially the same instruction set
• 3–6× the performance of the 8086
• Widely used inIBM PC AT and AT clones contemporary to it

• Introduced January 1, 1981 as Intel's first32-bit microprocessor
• Multi-chip CPU
• Object/capability architecture
• Microcoded operating system primitives
• One terabyte virtual address space
• Hardware support for fault tolerance
• Two-chip General Data Processor (GDP), consists of 43201 and 43202
• 43203 Interface Processor (IP) interfaces to I/O subsystem
• 43204 Bus Interface Unit (BIU) simplifies building multiprocessor systems
• 43205 Memory Control Unit (MCU)
• Architecture and execution unit internal data base paths: 32 bits
• Clock rates:
  • 5 MHz
  • 7 MHz
  • 8 MHz

• Introduced April 5, 1988
• RISC-like32-bit architecture
• Predominantly used in embedded systems
• Evolved from the capability processor developed for theBiiN joint venture withSiemens
• Many variants identified by two-letter suffixes

• Initial version 80860XR Introduced February 26, 1989
• RISC 32/64-bit architecture, with floating point pipeline characteristics very visible to programmer
• Used in theIntel iPSC/860Hypercube parallel supercomputer
• Mid-life kicker in the 80860XP processor (primarily a speed bump, some refinement/extension of instruction set)
• Used in theIntel Delta massively parallel supercomputer prototype, emplaced atCalifornia Institute of Technology
• Used in theIntel Paragon massively parallel supercomputer, emplaced atSandia National Laboratory

• Introduced August 23, 2000
• 32-bitRISC microprocessor based on theARM architecture
• Many variants, such as the PXA2xx applications processors, IOP3xx I/O processors and IXP2xxx and IXP4xx network processors

• Introduced October 17, 1985
• Clock rates:
  • 16 MHz, 5 MIPS
  • 20 MHz, 6 to 7 MIPS, introduced February 16, 1987
  • 25 MHz, 7.5 MIPS, introduced April 4, 1988
  • 33 MHz, 9.9 MIPS (9.4 SPECint92 on Compaq/i 16 KB L2), introduced April 10, 1989
• Data bus width: 32 bits, address bus: 32 bits
• 275,000 transistors at 1 μm
• Addressable memory 4 GB (4 × 1024³ B)
• Virtual memory 64 TB (64 × 1024⁴ B)^[12][13]
• First x86 chip to handle32-bit data sets
• Reworked and expanded memory protection support includingpaged virtual memory and virtual-86 mode, features required at the time byXenix andUnix. This memory capability spurred the development and availability ofOS/2 and is a fundamental requirement for modern operating systems likeLinux,Windows, andmacOS
• First used by Compaq in theDeskpro 386. Used in desktop computing
• Unlike the DX naming convention of the 486 chips, it had no math co-processor
• Later renamed Intel386 DX

• Introduced June 16, 1988
• Clock rates:
  • 16 MHz, 2.5 MIPS
  • 20 MHz, 3.1 MIPS, introduced January 25, 1989
  • 25 MHz, 3.9 MIPS, introduced January 25, 1989
  • 33 MHz, 5.1 MIPS, introduced October 26, 1992
• 32-bit internal architecture
• External data bus width: 16 bits
• External address bus width: 24 bits
• 275,000 transistors at 1 μm
• Addressable memory 16 MB
• Virtual memory 64 TB^[12]
• Narrower buses enable low-cost 32-bit processing
• Used in entry-level desktop and portable computing
• No math co-processor
• No commercial software used protected mode or virtual storage for many years
• Later renamed Intel386 SX

• Introduced January 16, 1989; discontinued June 15, 2001
• Variant of 386SX intended for embedded systems
• No "real mode", starts up directly in "protected mode"
• Replaced by much more successful80386EX from 1994

• Introduced October 15, 1990
• Clock rates:
  • 20 MHz, 4.21 MIPS
  • 25 MHz, 5.3 MIPS, introduced September 30, 1991
• 32-bit internal architecture
• External bus width: 16 bits
• 855,000 transistors at 1 μm
• Addressable memory 4 GB
• Virtual memory 64 TB^[12]
• First chip specifically made for portable computers because of low power consumption of chip
• Highly integrated, includes cache, bus, and memory controllers

• Introduced August 1994
• Variant of 80386SX intended forembedded systems
• Static core (i.e. may run as slowly (and thus, power efficiently) as desired) down to full halt
• On-chip peripherals:
  • Clock and power management
  • Timers/counters
  • Watchdog timer
  • Serial I/O units (sync and async) and parallel I/O
  • DMA
  • RAM refresh
  • JTAG test logic
• Significantly more successful than the 80376
• Used aboard several orbiting satellites and microsatellites
• Used in NASA'sFlightLinux project