تأريخ المعالجات الدقيقة

Progress of miniaturisation, and comparison of sizes of semiconductor manufacturing process nodes with some microscopic objects and visible light wavelengths

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ع1970

The first microprocessors were designed and manufactured in the 1970s. Intel's 4004 of 1971 is widely regarded as the first commercial microprocessor.[1]

Designers predominantly used MOSFET transistors with pMOS logic in the early 1970s, switching to nMOS logic after the mid-1970s. nMOS had the advantage that it could run on a single voltage, typically +5V, which simplified the power supply requirements and allowed it to be easily interfaced with the wide variety of +5V transistor-transistor logic (TTL) devices. nMOS had the disadvantage that it was more susceptible to electronic noise generated by slight impurities in the underlying silicon material, and it was not until the mid-1970s that these, sodium in particular, were successfully removed to the required levels. At that time, around 1975, nMOS quickly took over the market.[2]

This corresponded with the introduction of new semiconductor masking systems, notably the Micralign system from Perkin-Elmer. Micralign projected an image of the mask onto the silicon wafer, never touching it directly, which eliminated the previous problems when the mask would be lifted off the surface and take away some of the photoresist along with it, ruining the chips on that portion of the wafer.[3] By reducing the number of flawed chips, from about 70% to 10%, the cost of complex designs like early microprocessors fell by the same amount. Systems based on contact aligners cost on the order of $300 in single-unit quantities, the MOS 6502, designed specifically to take advantage of these improvements, cost only $25.[4]

This period also saw considerable experimentation with various word lengths. Early on, 4-bit processors were common, like the Intel 4004, simply because making a wider word length could not be accomplished cost-effectively in the room available on the small wafers of the era, especially when the majority would be defective. As yields improved, wafer sizes grew, and feature size continued to be reduced, more complex 8-bit designs emerged like the Intel 8080 and 6502. 16-bit processors emerged early but were expensive; by the decade's end, low-cost 16-bit designs like the Zilog Z8000 were becoming common. Some unusual word lengths were also produced, including 12-bit and 20-bit, often matching a design that had previously been implemented in a multi-chip format in a minicomputer. These had largely disappeared by the end of the decade as minicomputers moved to 32-bit formats.

Date Name Developer Max clock
(first version)
Word size
(bits)
Process Chips[5] Transistors MOSFET Ref
1971 4004 Intel 740 kHz 4 10 μm 1 2,250 pMOS [5]
1972 PPS-25 Fairchild 400 kHz 4   2 pMOS [6][أ]
1972 μPD700 NEC   4   1 [7]
1972 8008 Intel 500 kHz 8 10 μm 1 3,500 pMOS
1972 PPS-4 Rockwell 200 kHz 4   1 pMOS [8][9]
1973 IMP-16 National 715 kHz 16   5 pMOS [10][5][11]
1973 μCOM-4 NEC 2 MHz 4 7.5 μm 1 2,500 NMOS [12][13][7][5]
1973 TLCS-12 Toshiba 1 MHz 12 6 μm 1 2,800 silicon gates pMOS [14][15][5]
1973 Mini-D Burroughs 1 MHz 8   1 pMOS [16]
1974 IMP-8 National 715 kHz 8   3 pMOS [14]
1974 8080 Intel 2 MHz 8 6 μm 1 6,000 NMOS
1974 μCOM-8 NEC 2 MHz 8   1 NMOS [7][5]
1974 5065 Mostek 1.4 MHz 8   1 pMOS [17]
1974 μCOM-16 NEC 2 MHz 16   2 NMOS [7][5]
1974 IMP-4 National 500 kHz 4   3 pMOS [14]
1974 4040 Intel 740 kHz 4 10 μm 1 3,000 pMOS
1974 6800 Motorola 1 MHz 8 - 1 4,100 NMOS [14]
1974 TMS 1000 Texas Instruments 400 kHz 4 8 μm 1 8,000 pMOS,nMOS,cMOS
1974 PACE National 1.33 MHz 16   1 pMOS [18][19]
1974 ISP-8A/500 (SC/MP) National 1 MHz 8   1 pMOS
1975 6100 Intersil 4 MHz 12 - 1 4,000 CMOS [20][21]
1975 TLCS-12A Toshiba 1.2 MHz 12 - 1 pMOS [5]
1975 2650 Signetics 1.2 MHz 8   1 NMOS [14]
1975 PPS-8 Rockwell 256 kHz 8   1 pMOS [14]
1975 F-8 Fairchild 2 MHz 8   1 NMOS [14]
1975 CDP 1801 RCA 2 MHz 8 5 μm 2 5,000 CMOS [22][23]
1975 6502 MOS Technology 1 MHz 8 - 1 3,510 NMOS (dynamic)
1975 PFL-16A (MN 1610) Panafacom 2 MHz 16 - 1 NMOS [5]
1975 BPC Hewlett Packard 10 MHz 16 - 1 6,000 (+ ROM) NMOS [24][25]
1975 MCP-1600 Western Digital 3.3 MHz 16 - 3 NMOS [26]
1975 CP1600 General Instrument 3.3 MHz 16   1 NMOS [18][27][28][5]
1976 CDP 1802 RCA 6.4 MHz 8   1 CMOS [29][30]
1976 Z-80 Zilog 2.5 MHz 8 4 μm 1 8,500 NMOS
1976 TMS9900 Texas Instruments 3.3 MHz 16 - 1 8,000 nMOS
1976 8x300 Signetics 8 MHz 8   1 Bipolar [31][32]
1976 WD16 Western Digital 3.3 MHz 16 5 NMOS [33][26]
1977 Bellmac-8 (WE212) Bell Labs 2.0 MHz 8 5 μm 1 7,000 CMOS
1977 8085 Intel 3.0 MHz 8 3 μm 1 6,500 nMOS
1977 MC14500B Motorola 1.0 MHz 1 1 CMOS
1978 6809 Motorola 1 MHz 8 5 μm 1 9,000 NMOS
1978 8086 Intel 5 MHz 16 3 μm 1 29,000 nMOS
1978 6801 Motorola - 8 5 μm 1 35,000 nMOS
1979 Z8000 Zilog - 16 - 1 17,500 nMOS
1979 8088 Intel 5 MHz 8/16[ب] 3 μm 1 29,000 NMOS (HMOS)
1979 68000 Motorola 8 MHz 16/32[ت] 3.5 μm 1 68,000 NMOS (HMOS) [34]


1980s

As Moore's Law continued to drive the industry towards more complex chip designs, the expected widespread move from 8-bit designs of the 1970s to 16-bit designs almost didn't occur; instead, new 32-bit designs like the Motorola 68000 and National Semiconductor NS32000 emerged that offered far more performance. The only widespread use of 16-bit systems was in the IBM PC, which had selected the Intel 8088 in 1979 before the new designs had matured.

Another change was the move to CMOS gates as the primary method of building complex CPUs. CMOS had been available since the early 1970s; RCA introduced the COSMAC processor using CMOS in 1974. Whereas earlier systems used a single transistor as the basis for each "gate", CMOS used a two-sided design, essentially making it twice as expensive to build. Its advantage was that its logic was not based on the voltage of a transistor compared to the silicon substrate, but the difference in voltages between the two sides, which was detectable at much lower power levels. As processor complexity continued to grow, power dissipation had become a significant concern and chips were prone to overheating; CMOS greatly reduced this problem and quickly took over the market.[35] This was aided by the uptake of CMOS by Japanese firms while US firms remained on nMOS, giving the Japanese industry a major advance during the 1980s.[36]

Semiconductor fabrication techniques continued to improve throughout. The Micralign, which had "created the modern IC industry", was obsolete by the early 1980s. They were replaced by the new steppers, which used high magnifications and extremely powerful light sources to allow a large mask to be copied onto the wafer at ever-smaller sizes. This technology allowed the industry to break below the former 1 micron limit.

Key home computers in the early part of the decade predominantly use processors developed in the 1970s. Versions of the 6502, first released in 1975, powered the Commodore 64, Apple II, BBC Micro, and Atari 8-bit family. The 8-bit Zilog Z80 (1976) is at the core of the ZX Spectrum, MSX systems and many others. The 8086-based IBM PC, launched in 1981, started the move to 16-bit, but was soon passed by the 68000-based 16/32-bit Macintosh, then the Atari ST and Amiga. IBM PC compatibles moved to 32-bit with the introduction of the Intel 80386 in late 1985, although 386-based systems were considerably expensive at the time.

In addition to ever-growing word lengths, microprocessors began to add additional functional units that had previously been optional external parts. By the middle of the decade, memory management units (MMUs) were becoming commonplace, first appearing on designs like the Intel 80286 and Motorola 68030. By the end of the decade, floating point units (FPUs) were being added, first appearing on 1989s Intel 486 and followed the next year by the Motorola 68040.

Another change that began during the 1980s involved overall design philosophy with the emergence of the reduced instruction set computer, or RISC. Although the concept was first developed by IBM in the 1970s, the company did not introduce powerful systems based on it, largely for fear of cannibalizing their sales of larger mainframe systems. Market introduction was driven by smaller companies like MIPS Technologies, SPARC and ARM. These companies did not have access to high-end fabrication like Intel and Motorola, but were able to introduce chips that were highly competitive with those companies with a fraction of the complexity. By the end of the decade, every major vendor was introducing a RISC design of their own, like the IBM POWER, Intel i860 and Motorola 88000.

Date Name Developer Max Clock
(first version)
Word size
(bits)
Process Transistors
1980 16032 National Semiconductor - 16/32 - 60,000
1980 BELLMAC-32/WE 32000 Bell Labs 32 150,000
1981 6120 Harris Corporation 10 MHz 12 - 20,000 (CMOS)[37]
1981 ROMP IBM 10 MHz 32 2 μm 45,000
1981 T-11 DEC 2.5 MHz 16 5 μm 17,000 (NMOS)
1982 RISC-I[38] UC Berkeley 1 MHz - 5 μm 44,420 (NMOS)
1982 FOCUS Hewlett Packard 18 MHz 32 1.5 μm 450,000
1982 80186 Intel 6 MHz 16 - 55,000
1987 80C186 Intel 10 MHz 16 - 56,000 (CMOS)
1982 80188 Intel 8 MHz 8/16 - 29,000
1982 80286 Intel 6 MHz 16 1.5 μm 134,000
1983 RISC-II UC Berkeley 3 MHz - 3 μm 40,760 (NMOS)
1983 MIPS[39] Stanford University 2 MHz 32 3 μm 25,000
1983 65816 Western Design Center - 16 - -
1984 68020 Motorola 16 MHz 32 2 μm 190,000
1984 NS32032 National Semiconductor - 32 - 70,000
1984 V20 NEC 5 MHz 8/16 - 63,000
1985 80386 Intel 12 MHz 32 1.5 μm 275,000
1985 MicroVax II 78032 DEC 5 MHz 32 3.0 μm 125,000
1985 R2000 MIPS 8 MHz 32 2 μm 115,000
1985[40] Novix NC4016 Harris Corporation 8 MHz 16 3 μm[41] 16,000[42]
1986 Z80000 Zilog - 32 - 91,000
1986 SPARC MB86900 Fujitsu[43][44][45] 15 MHz 32 0.8 μm 800,000
1986 V60[46] NEC 16 MHz 16/32 1.5 μm 375,000
1987 CVAX 78034 DEC 12.5 MHz 32 2.0 μm 134,000
1987 ARM2 Acorn 8 MHz 32 2 μm 25,000[47]
1987 Gmicro/200[48] Hitachi - - 1 μm 730,000
1987 68030 Motorola 16 MHz 32 1.3 μm 273,000
1987 V70[46] NEC 20 MHz 16/32 1.5 μm 385,000
1988 R3000 MIPS 25 MHz 32 1.2 μm 120,000
1988 80386SX Intel 12 MHz 16/32 - -
1988 i960 Intel 10 MHz 33/32 1.5 μm 250,000
1989 i960CA[49] Intel 16 – 33 MHz 33/32 0.8 μm 600,000
1989 VAX DC520 "Rigel" DEC 35 MHz 32 1.5 μm 320,000
1989 80486 Intel 25 MHz 32 1 μm 1,180,000
1989 i860 Intel 25 MHz 32 1 μm 1,000,000

1990s

The 32-bit microprocessor dominated the consumer market in the 1990s. Processor clock speeds increased by more than tenfold between 1990 and 1999, and 64-bit processors began to emerge later in the decade. In the 1990s, microprocessors no longer used the same clock speed for the processor and the RAM. Processors began to have a front-side bus (FSB) clock speed used in communication with RAM and other components. Typically, the processor itself ran at a clock speed that was a multiple of the FSB clock speed. Intel's Pentium III, for example, had an internal clock speed of 450–600 MHz and an FSB speed of 100–133 MHz. Only the processor's internal clock speed is shown here.

Date Name Developer Clock Word size
(bits)
Process Transistors
(millions)
Threads
1990 68040 Motorola 40 MHz 32 - 1.2
1990 POWER1 IBM 20–30 MHz 32 1,000 nm 6.9
1991 R4000 MIPS Computer Systems 100 MHz 64 800 nm 1.35
1991 NVAX DEC 62.5–90.91 MHz 32 750 nm 1.3
1991 RSC IBM 33 MHz 32 800 nm 1.0[50]
1992 SH-1 Hitachi 20 MHz[51] 32 800 nm 0.6[52]
1992 Alpha 21064 DEC 100–200 MHz 64 750 nm 1.68
1992 microSPARC I Sun 40–50 MHz 32 800 nm 0.8
1992 PA-7100 Hewlett Packard 100 MHz 32 800 nm 0.85[53]
1992 486SLC Cyrix 40 MHz 16
1993 HARP-1 Hitachi 120 MHz - 500 nm 2.8[54]
1993 PowerPC 601 IBM, Motorola 50–80 MHz 32 600 nm 2.8
1993 Pentium Intel 60–66 MHz 32 800 nm 3.1
1993 POWER2 IBM 55–71.5 MHz 32 720 nm 23
1994 microSPARC II Fujitsu 60–125 MHz - 500 nm 2.3
1994 S/390 G1 IBM - 32 -
1994 68060 Motorola 50 MHz 32 600 nm 2.5
1994 Alpha 21064A DEC 200–300 MHz 64 500 nm 2.85
1994 R4600 QED 100–125 MHz 64 650 nm 2.2
1994 PA-7200 Hewlett Packard 125 MHz 32 550 nm 1.26
1994 PowerPC 603 IBM, Motorola 60–120 MHz 32 500 nm 1.6
1994 PowerPC 604 IBM, Motorola 100–180 MHz 32 500 nm 3.6
1994 PA-7100LC Hewlett Packard 100 MHz 32 750 nm 0.90
1995 Alpha 21164 DEC 266–333 MHz 64 500 nm 9.3
1995 S/390 G2 IBM - 32 -
1995 UltraSPARC Sun 143–167 MHz 64 470 nm 5.2
1995 SPARC64 HAL Computer Systems 101–118 MHz 64 400 nm -
1995 Pentium Pro Intel 150–200 MHz 32 350 nm 5.5
1996 Alpha 21164A DEC 400–500 MHz 64 350 nm 9.7
1995 S/390 G3 IBM - 32 -
1996 K5 AMD 75–100 MHz 32 500 nm 4.3
1996 R10000 MTI 150–250 MHz 64 350 nm 6.7
1996 R5000 QED 180–250 MHz - 350 nm 3.7
1996 SPARC64 II HAL Computer Systems 141–161 MHz 64 350 nm -
1996 PA-8000 Hewlett-Packard 160–180 MHz 64 500 nm 3.8
1996 POWER2 Super Chip (P2SC) IBM 150 MHz 32 290 nm 15
1997 SH-4 Hitachi 200 MHz - 200 nm[55] 10[56]
1997 RS64 IBM 125 MHz 64 ? nm ?
1997 Pentium II Intel 233–300 MHz 32 350 nm 7.5
1997 PowerPC 620 IBM, Motorola 120–150 MHz 64 350 nm 6.9
1997 UltraSPARC IIs Sun 250–400 MHz 64 350 nm 5.4
1997 S/390 G4 IBM 370 MHz 32 500 nm 7.8
1997 PowerPC 750 IBM, Motorola 233–366 MHz 32 260 nm 6.35
1997 K6 AMD 166–233 MHz 32 350 nm 8.8
1998 RS64-II IBM 262 MHz 64 350 nm 12.5
1998 Alpha 21264 DEC 450–600 MHz 64 350 nm 15.2
1998 MIPS R12000 SGI 270–400 MHz 64 250180 nm 6.9
1998 RM7000 QED 250–300 MHz - 250 nm 18
1998 SPARC64 III HAL Computer Systems 250–330 MHz 64 240 nm 17.6
1998 S/390 G5 IBM 500 MHz 32 250 nm 25
1998 PA-8500 Hewlett Packard 300–440 MHz 64 250 nm 140
1998 POWER3 IBM 200 MHz 64 250 nm 15
1999 S/390 G6 IBM 550-637 MHz 32 -
1999 Emotion Engine Sony, Toshiba 294–300 MHz - 180–65 nm[57] 13.5[58]
1999 Pentium III Intel 450–600 MHz 32 250 nm 9.5
1999 RS64-III IBM 450 MHz 64 220 nm 34 2
1999 PowerPC 7400 Motorola 350–500 MHz 32 200–130 nm 10.5
1999 Athlon AMD 500–1000 MHz 32 250 nm 22


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2000s

64-bit processors became mainstream in the 2000s. Microprocessor clock speeds reached a ceiling because of the heat dissipation barrier. Instead of implementing expensive and impractical cooling systems, manufacturers turned to parallel computing in the form of the multi-core processor. Overclocking had its roots in the 1990s, but came into its own in the 2000s. Off-the-shelf cooling systems designed for overclocked processors became common, and the gaming PC had its advent as well. Over the decade, transistor counts increased by about an order of magnitude, a trend continued from previous decades. Process sizes decreased about fourfold, from 180 nm to 45 nm.

Date Name Developer Clock Process Transistors
(millions)
Cores per die /
Dies per module
2000 Athlon XP AMD 1.33–1.73 GHz 180 nm 37.5 1 / 1
2000 Duron AMD 550 MHz–1.3 GHz 180 nm 25 1 / 1
2000 RS64-IV IBM 600–750 MHz 180 nm 44 1 / 2
2000 Pentium 4 Intel 1.3–2 GHz 180–130 nm 42 1 / 1
2000 SPARC64 IV Fujitsu 450–810 MHz 130 nm - 1 / 1
2000 z900 IBM 918 MHz 180 nm 47 1 / 12, 20
2001 MIPS R14000 SGI 500–600 MHz 130 nm 7.2 1 / 1
2001 POWER4 IBM 1.1–1.4 GHz 180–130 nm 174 2 / 1, 4
2001 UltraSPARC III Sun 750–1200 MHz 130 nm 29 1 / 1
2001 Itanium Intel 733–800 MHz 180 nm 25 1 / 1
2001 PowerPC 7450 Motorola 733–800 MHz 180–130 nm 33 1 / 1
2002 SPARC64 V Fujitsu 1.1–1.35 GHz 130 nm 190 1 / 1
2002 Itanium 2 Intel 0.9–1 GHz 180 nm 410 1 / 1
2003 PowerPC 970 IBM 1.6–2.0 GHz 130–90 nm 52 1 / 1
2003 Pentium M Intel 0.9–1.7 GHz 130–90 nm 77 1 / 1
2003 Opteron AMD 1.4–2.4 GHz 130 nm 106 1 / 1
2004 POWER5 IBM 1.65–1.9 GHz 130–90 nm 276 2 / 1, 2, 4
2004 PowerPC BGL IBM 700 MHz 130 nm 95 2 / 1
2005 IBM z9 IBM
2005 Opteron "Athens" AMD 1.6–3.0 GHz 90 nm 114 1 / 1
2005 Pentium D Intel 2.8–3.2 GHz 90 nm 115 1 / 2
2005 Athlon 64 X2 AMD 2–2.4 GHz 90 nm 243 2 / 1
2005 PowerPC 970MP IBM 1.2–2.5 GHz 90 nm 183 2 / 1
2005 UltraSPARC IV Sun 1.05–1.35 GHz 130 nm 66 2 / 1
2005 UltraSPARC T1 Sun 1–1.4 GHz 90 nm 300 8 / 1
2005 Xenon IBM 3.2 GHz 90–45 nm 165 3 / 1
2006 Core Duo Intel 1.1–2.33 GHz 90–65 nm 151 2 / 1
2006 Core 2 Intel 1.06–2.67 GHz 65–45 nm 291 2 / 1, 2
2006 Cell/B.E. IBM, Sony, Toshiba 3.2–4.6 GHz 90–45 nm 241 1+8 / 1
2006 Itanium "Montecito" Intel 1.4–1.6 GHz 90 nm 1720 2 / 1
2007 POWER6 IBM 3.5–4.7 GHz 65 nm 790 2 / 1
2007 SPARC64 VI Fujitsu 2.15–2.4 GHz 90 nm 543 2 / 1
2007 UltraSPARC T2 Sun 1–1.4 GHz 65 nm 503 8 / 1
2007 TILE64 Tilera 600–900 MHz 90–45 nm ? 64 / 1
2007 Opteron "Barcelona" AMD 1.8–3.2 GHz 65 nm 463 4 / 1
2007 PowerPC BGP IBM 850 MHz 90 nm 208 4 / 1
2008 Phenom AMD 1.8–2.6 GHz 65 nm 450 2, 3, 4 / 1
2008 z10 IBM 4.4 GHz 65 nm 993 4 / 7
2008 PowerXCell 8i IBM 2.8–4.0 GHz 65 nm 250 1+8 / 1
2008 SPARC64 VII Fujitsu 2.4–2.88 GHz 65 nm 600 4 / 1
2008 Atom Intel 0.8–1.6 GHz 65–45 nm 47 1 / 1
2008 Core i7 Intel 2.66–3.2 GHz 45–32 nm 730 2, 4, 6 / 1
2008 TILEPro64 Tilera 600–866 MHz 90–45 nm ? 64 / 1
2008 Opteron "Shanghai" AMD 2.3–2.9 GHz 45 nm 751 4 / 1
2009 Phenom II AMD 2.5–3.2 GHz 45 nm 758 2, 3, 4, 6 / 1
2009 Opteron "Istanbul" AMD 2.2–2.8 GHz 45 nm 904 6 / 1

2010s

A new trend appears, the multi-chip module made of several chiplets. This is multiple monolithic chips in a single package. This allows higher integration with several smaller and easier to manufacture chips.

Date Name Developer Clock Process Transistors
(millions)
Cores per die /
Dies per module
Threads
per core
2010 POWER7 IBM 3–4.14 GHz 45 nm 1200 4, 6, 8 / 1, 4 4
2010 Itanium "Tukwila" Intel 2 GHz 65 nm 2000 2, 4 / 1 2
2010 Opteron "Magny-cours" AMD 1.7–2.4 GHz 45 nm 1810 4, 6 / 2 1
2010 Xeon "Nehalem-EX" Intel 1.73–2.66 GHz 45 nm 2300 4, 6, 8 / 1 2
2010 z196 IBM 3.8–5.2 GHz 45 nm 1400 4 / 1, 6 1
2010 SPARC T3 Sun 1.6 GHz 45 nm 2000 16 / 1 8
2010 SPARC64 VII+ Fujitsu 2.66–3.0 GHz 45 nm ? 4 / 1 2
2010 Intel "Westmere" Intel 1.86–3.33 GHz 32 nm 1170 4–6 / 1 2
2011 Intel "Sandy Bridge" Intel 1.6–3.4 GHz 32 nm 995[59] 2, 4 / 1 (1,) 2
2011 AMD Llano AMD 1.0–1.6 GHz 40 nm 380[60] 1, 2 / 1 1
2011 Xeon E7 Intel 1.73–2.67 GHz 32 nm 2600 4, 6, 8, 10 / 1 1–2
2011 Power ISA BGQ IBM 1.6 GHz 45 nm 1470 18 / 1 4
2011 SPARC64 VIIIfx Fujitsu 2.0 GHz 45 nm 760 8 / 1 2
2011 FX "Bulldozer" Interlagos AMD 3.1–3.6 GHz 32 nm 1200[61] 4–8 / 2 1
2011 SPARC T4 Oracle 2.8–3 GHz 40 nm 855 8 / 1 8
2012 SPARC64 IXfx Fujitsu 1.848 GHz 40 nm 1870 16 / 1 2
2012 zEC12 IBM 5.5 GHz 32 nm 2750 6 / 6 1
2012 POWER7+ IBM 3.1–5.3 GHz 32 nm 2100 8 / 1, 2 4
2012 Itanium "Poulson" Intel 1.73–2.53 GHz 32 nm 3100 8 / 1 2
2013 Intel "Haswell" Intel 1.9–4.4 GHz 22 nm 1400 4 / 1 2
2013 SPARC64 X Fujitsu 2.8–3 GHz 28 nm 2950 16 / 1 2
2013 SPARC T5 Oracle 3.6 GHz 28 nm 1500 16 / 1 8
2014 POWER8 IBM 2.5–5 GHz 22 nm 4200 6, 12 / 1, 2 8
2014 Intel "Broadwell" Intel 1.8-4 GHz 14 nm 1900 2, 4, 6, 8, 12, 16 / 1, 2, 4 2
2015 z13 IBM 5 GHz 22 nm 3990 8 / 1 2
2015 A8-7670K AMD 3.6 GHz 28 nm 2410 4 / 1 1
2016 RISC-V E31[62] SiFive 320 MHz 28 nm ? 1 1
2017 Zen AMD 3.2–4.1 GHz 14 nm 4800 8, 16, 32 / 1, 2, 4 2
2017 z14 IBM 5.2 GHz 14 nm 6100 10 / 1 2
2017 POWER9 IBM 4 GHz 14 nm 8000 12, 24 / 1 4, 8
2017 SPARC M8[63] Oracle 5 GHz 20 nm ~10,000[64] 32 8
2017 RISC-V U54-MC[65] SiFive 1.5 GHz 28 nm 250 4 1
2018 Intel "Cannon Lake" Intel 2.2–3.2 GHz 10 nm ? 2 / 1 2
2018 Zen+ AMD 2.8–3.7 GHz 12 nm 4800 2, 4, 6, 8, 12, 16, 24, 32 / 1, 2, 4 1, 2
2018 RISC-V U74-MC[66] SiFive 1.5 GHz ? ? 4 1
2019 Zen 2 AMD 2–4.7 GHz 7 nm 3900 6, 8, 12, 16, 24, 32, 64 / 1, 2, 4 2
2019 z15 IBM 5.2 GHz 14 nm 9200 12 / 1 2

2020s

Date Name Developer Clock Process Transistors
(millions)
Cores per die /
Dies per module
Threads
per core
2020 Zen 3 AMD 3.4–4.9 GHz 7 nm ? 6, 8, 12, 16 / 2
2020 M1 Apple 3.2 GHz 5  nm 16000 8 1
2021 M1 Max Apple 3.2 GHz 5 nm 57000 10 1
April 2022 IBM Telum IBM >5 GHz 7 nm 22000 8 1
November 2022 M1 Ultra Apple 3.2 GHz __  nm 114000 20 1


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انظر أيضاً

المراجع والملاحظات

المراجع
  1. ^ "The Story of the Intel 4004". Intel.
  2. ^ "NMOS versus PMOS".
  3. ^ "Perkin Elmer - Micralign Projection Mask Alignment System".
  4. ^ "The MOS 6502 and the Best Layout Guy in the World". swtch.com. 2011-01-03. Retrieved 2014-08-09.
  5. ^ أ ب ت ث ج ح خ د ذ ر Belzer, Jack; Holzman, Albert G.; Kent, Allen (1978). Encyclopedia of Computer Science and Technology: Volume 10 - Linear and Matrix Algebra to Microorganisms: Computer-Assisted Identification. CRC Press. p. 402. ISBN 9780824722609.
  6. ^ Ogdin 1975, pp. 57–59, 77
  7. ^ أ ب ت ث "1970s: Development and evolution of microprocessors" (PDF). Semiconductor History Museum of Japan. Archived from the original (PDF) on 2019-06-27. Retrieved 16 September 2020.
  8. ^ Ogdin 1975, pp. 72, 77
  9. ^ "Rockwell PPS-4". The Antique Chip Collector's Page. Retrieved 2010-06-14.
  10. ^ Ogdin 1975, pp. 70, 77
  11. ^ "National Semiconductor IMP-16". The Antique Chip Collector's Page. Archived from the original on 2002-02-07. Retrieved 2010-06-14.
  12. ^ Ryoichi Mori; Hiroaki Tajima; Morihiko Tajima; Yoshikuni Okada (October 1977). "Microprocessors in Japan". Euromicro Newsletter. 3 (4): 50–7 (51, Table 2.2). doi:10.1016/0303-1268(77)90111-0.
  13. ^ "NEC 751 (uCOM-4)". The Antique Chip Collector's Page. Archived from the original on 2011-05-25. Retrieved 2010-06-11.
  14. ^ أ ب ت ث ج ح خ Ogdin 1975, p. 77
  15. ^ "1973: 12-bit engine-control microprocessor (Toshiba)" (PDF). Semiconductor History Museum of Japan. Archived from the original (PDF) on 2019-06-27. Retrieved 16 September 2020.
  16. ^ Ogdin 1975, pp. 55, 77
  17. ^ Ogdin 1975, pp. 65, 77
  18. ^ أ ب David Russell (February 1978). "Microprocessor survey". Microprocessors. 2 (1): 13–20, See p. 18. doi:10.1016/0308-5953(78)90071-5.
  19. ^ Allen Kent, James G. Williams, ed. (1990). "Evolution of Computerized Maintenance Management to Generation of Random Numbers". Encyclopedia of Microcomputers. Vol. 7. Marcel Dekker. p. 336. ISBN 0-8247-2706-1.
  20. ^ Little, Jeff (2009-03-04). "Intersil Intercept Jr". ClassicCmp.
  21. ^ "Intersil IM6100 CMOS 12 Bit Microprocessor family databook" (PDF).
  22. ^ "RCA COSMAC 1801". The Antique Chip Collector's Page. Retrieved 2010-06-14.
  23. ^ "CDP 1800 μP Commercially available" (PDF). Microcomputer Digest. 2 (4): 1–3. October 1975.
  24. ^ "Hybrid Microprocessor". Retrieved 2008-06-15.
  25. ^ "HP designs Custom 16-bit μC Chip" (PDF). Microcomputer Digest. 2 (4): 8. October 1975.
  26. ^ أ ب MCP-1600 Microprocessor Users Manual (PDF). Western Digital. 1975. Retrieved 28 April 2022.
  27. ^ "Microprocessors — The Early Years 1971–1974". The Antique Chip Collector's Page. Retrieved 2010-06-16.
  28. ^ "CP1600 16-Bit Single-Chip Microprocessor" (PDF). data sheet. General Instrument. 1977. Archived from the original (PDF) on 2011-05-26. Retrieved 2010-06-18.
  29. ^ "RCA COSMAC 1802". The Antique Chip Collector's Page. Archived from the original on 2013-01-02. Retrieved 2010-06-14.
  30. ^ "CDP 1802" (PDF). Microcomputer Digest. 2 (10): 1, 4. April 1976.
  31. ^ Hans Hoffman; John Nemec (April 1977). "A fast microprocessor for control applications". Euromicro Newsletter. 3 (3): 53–59. doi:10.1016/0303-1268(77)90010-4.
  32. ^ "Microprocessors — The Explosion 1975–1976". The Antique Chip Collector's Page. Archived from the original on 2009-09-09. Retrieved 2010-06-18.
  33. ^ "WD16 Microcomputer Programmer's Reference Manual" (PDF). Western Digital. Retrieved 10 December 2021.
  34. ^ "Chip Hall of Fame: Motorola MC68000 Microprocessor". IEEE Spectrum. Institute of Electrical and Electronics Engineers. 30 June 2017. Retrieved 19 June 2019.
  35. ^ Kuhn, Kelin (2018). "CMOS and Beyond CMOS: Scaling Challenges". High Mobility Materials for CMOS Applications. Woodhead Publishing. p. 1. ISBN 9780081020623.
  36. ^ Gilder, George (1990). Microcosm: The Quantum Revolution In Economics And Technology. Simon and Schuster. pp. 144–5. ISBN 9780671705923.
  37. ^ Harris CMOS Digital Data Book (PDF). pp. 4–3–21.
  38. ^ "Berkeley Hardware Prototypes". Retrieved 2008-06-15.
  39. ^ Patterson, David A. (1985). "Reduced instruction set computers". Communications of the ACM. 28: 8–21. doi:10.1145/2465.214917. S2CID 1493886.
  40. ^ "Forth chips list". UltraTechnology. 2010.
  41. ^ Koopman, Philip J. (1989). "4.4 Architecture of the NOVIX NC4016". Stack Computers: the new wave. E. Horwood. ISBN 0745804187.
  42. ^ Hand, Tom (1994). "The Harris RTX 2000 Microcontroller" (PDF). Journal of Forth Application and Research. 6 (1). ISSN 0738-2022.
  43. ^ "Fujitsu to take ARM into the realm of Super". The CPU Shack Museum. June 21, 2016. Retrieved 30 June 2019.
  44. ^ "Fujitsu SPARC". cpu-collection.de. Retrieved 30 June 2019.
  45. ^ "Timeline". SPARC International. Retrieved 30 June 2019.
  46. ^ أ ب Kimura S, Komoto Y, Yano Y (1988). "Implementation of the V60/V70 and its FRM function". IEEE Micro. 8 (2): 22–36. doi:10.1109/40.527. S2CID 9507994.
  47. ^ C Green; P Gülzow; L Johnson; K Meinzer; J Miller (Mar–Apr 1999). "The Experimental IHU-2 Aboard P3D". Amsat Journal. 22 (2). The first processor using these principles, called ARM-1, was fabricated by VLSI in April 1985, and gave startling performance for the time, whilst using barely 25,000 transistors
  48. ^ Inayoshi H, Kawasaki I, Nishimukai T, Sakamura K (1988). "Realization of Gmicro/200". IEEE Micro. 8 (2): 12–21. doi:10.1109/40.526. S2CID 36938046.
  49. ^ "Intel i960 Embedded Microprocessor". National High Magnetic Field Laboratory. Florida State University. 3 March 2003. Archived from the original on 3 March 2003. Retrieved 29 June 2019.
  50. ^ (1992) "IBM Single Chip RISC Processor (RSC)".: 200–4, IEEE Computer Society. 
  51. ^ "Embedded-DSP SuperH Family and Its Applications" (PDF). Hitachi Review. Hitachi. 47 (4): 121–7. 1998. S2CID 43356065. Archived from the original (PDF) on 2019-02-25. Retrieved 5 July 2019.
  52. ^ "SH Microprocessor Leading the Nomadic Era" (PDF). Semiconductor History Museum of Japan. Retrieved 27 June 2019.
  53. ^ "PA-RISC Processors". Retrieved 2008-05-11.
  54. ^ "HARP-1: A 120 MHz Superscalar PA-RISC Processor" (PDF). Hitachi. Retrieved 19 June 2019.
  55. ^ "Entertainment Systems and High-Performance Processor SH-4" (PDF). Hitachi Review. Hitachi. 48 (2): 58–63. 1999. S2CID 44852046. Archived from the original (PDF) on 2019-02-21. Retrieved 27 June 2019.
  56. ^ "Remembering the Sega Dreamcast". Bit-Tech. September 29, 2009. Retrieved 18 June 2019.
  57. ^ "EMOTION ENGINE® AND GRAPHICS SYNTHESIZER USED IN THE CORE OF PLAYSTATION® BECOME ONE CHIP" (PDF). Sony. April 21, 2003. Retrieved 26 June 2019.
  58. ^ Hennessy, John L.; Patterson, David A. (29 May 2002). Computer Architecture: A Quantitative Approach (3 ed.). Morgan Kaufmann. p. 491. ISBN 978-0-08-050252-6. Retrieved 9 April 2013.
  59. ^ Anand Lal Shimpi (10 January 2011). "A Closer Look at the Sandy Bridge Die". AnandTech.
  60. ^ renethx (10 November 2011). "Cedar (HD 5450) and Zacate (E350) are manufactured in TSMC 40 nm process". AMD Zacate — the next great HTPC chip?. {{cite book}}: |work= ignored (help)
  61. ^ "AMD Revises Bulldozer Transistor Count: 1.2B, not 2B". AnandTech. 2 December 2011.
  62. ^ "SiFive - HiFive1". Archived from the original on 2016-11-30.
  63. ^ "Sparc M8 processor" (PDF). Oracle main website. Oracle Corp. Retrieved 3 March 2019.
  64. ^ "Is M8 the Last Hurrah for Oracle Sparc?". 18 September 2017.
  65. ^ "SiFive - HiFive1". Archived from the original on 2017-10-18.
  66. ^ "SiFive Introduces 7 Series RISC-V Cores".
ملاحظات
  1. ^ According to Ogdin 1975, the Fairchild PPS-25 was first delivered in 2Q 1971 and the Intel 4004 in 4Q 1971.
  2. ^ The Intel 8088 had an 8-bit external data bus, but internally used a 16-bit architecture.
  3. ^ The Motorola 68000 had a 16-bit external data bus, but internally used 32-bit registers.