Thursday, September 18, 2008

The expansion of Intel Processors(Desktop)

The expansion of Intel Processors(Desktop)

1: Pentium 1 (PI)
(P5-Micro Architecture )

(60-200 MHz)

2: Pentium 2 (PII)
(
P6-Micro Architecture)
(223-450 MHz)


3: Pentium 3 (PIII)
(P6-
Micro Architecture)
(450MHz-1.4GHz)


4: Pentium 4(P4)
(Netburst-
Micro Architecture)
(1.3-3.8 GHz)

5: Pentium 4 Extreme Edition(P4EE)
(Netburst-Micro Architecture)
(3.2-3.73 GHz)

6: Pentium D(PD)
(Netburst-
Micro Architecture)
(2.66-3.6 GHz)


7: Pentium Extreme Edition(PEE)

(Netburst-Micro Architecture)
(3.2-3.73 GHz)

8: Pentium Dual Core(PDC)
(Core-
Micro Architecture)
(1.6-2.5 GHz)

9:Intel Core 2 Duo(C2D)
(Core/Penryn
-Micro Architecture)
(1.8-3.33GHz)

10:Core 2 Quad(C2Q)
(Core/Penryn
-Micro Architecture)
(2.4-3.0 GHz)

11:Core 2 Extreme(C2E)
(Core/Penryn
-Micro Architecture)
(2.6-3.2GHz)


12:Intel Core i7
(Nehalem-Micro Architecture)
(2.66-2.93GHz)


13:Intel Core i7 Extreme Edition

(Nehalem-Micro Architecture)
(3.2GHz)

Upcoming -->>
Nehalem
(2008/09)>>Westmere(2009)>>SandyBrige(2010)>>
Ivy Brige(2011)>> Haswell(2012)



Details:-

1)Pentium 1

  • Bus width 64 bits
  • System bus speed 60 or 66 MHz
  • Address bus 32 bits
  • Address 4GB memory
  • Runs on 5 volts
  • Used in desktops
  • 16 KB of L1 cache
  • P5 - 0.8 µm process technology
* Introduced March 22, 1993
* Number of transistors 3.1 million
* Socket 4 273 pin PGA processor package
* Package dimensions 2.16" x 2.16"
* Family 5 model 1
* Variants
o 60 MHz with 100 MIPS (70.4 SPECint92, 55.1 SPECfp92 on Xpress 256 KB L2)
o 66 MHz with 112 MIPS (77.9 SPECint92, 63.6 SPECfp92 on Xpress 256 KB L2)

  • P54 - 0.6 µm process technology

* Socket 7 296/321 pin PGA package
* Number of transistors 3.2 million
* Variants
o 75 MHz Introduced October 10, 1994
o 90 MHz Introduced March 7, 1994
o 100 MHz Introduced March 7, 1994
o 120 MHz Introduced March 27, 1995
  • P54C - 0.35 µm process technology
* Number of transistors 3.3 million
* 90 mm² die size
* Family 5 model 2
* Variants
o 120 MHz Introduced March, 1995
o 133 MHz Introduced June, 1995
o 150 MHz Introduced January 4, 1996
o 166 MHz Introduced January 4, 1996
o 200 MHz Introduced June 10, 1996

2) Pentium 2
  • Introduced May 7, 1997
  • Pentium Pro with MMX and improved 16-bit performance
  • 242-pin Slot 1 (SEC) processor package
  • Address 64GB memory
  • Number of transistors 7.5 million
  • 32 KB L1 cache
  • 512 KB ½ speed external L2 cache
  • Klamath - 0.35 µm process technology (233, 266, 300 MHz)
* 66 MHz system bus speed
* Family 6 model 3
* Variants
o 233 MHz Introduced May 7, 1997
o 266 MHz Introduced May 7, 1997
o 300 MHz Introduced May 7, 1997

  • Deschutes - 0.25 µm process technology (333, 350, 400, 450 MHz)

* Introduced January 26, 1998
* 66 MHz system bus speed (333 MHz variant), 100 MHz system bus speed for all models after
* Family 6 model 5
* Variants
o 333 MHz Introduced January 26, 1998
o 350 MHz Introduced April 15, 1998
o 400 MHz Introduced April 15, 1998
o 450 MHz Introduced August 24, 1998


3)Pentium 3

  • Katmai - 0.25 µm process technology
* Introduced February 26, 1999
* Improved PII, i.e. P6-based core, now including Streaming SIMD Extensions (SSE)
* Number of transistors 9.5 million
* 512 KB ½ speed L2 External cache
* 242-pin Slot 1 SECC2 (Single Edge Contact cartridge 2) processor package
* System Bus Speed 100 MHz, 133 MHz (B-models)
* Variants
o 450 MHz Introduced February 26, 1999
o 500 MHz Introduced February 26, 1999
o 550 MHz Introduced May 17, 1999
o 600 MHz Introduced August 2, 1999
o 533 MHz Introduced (133 MHz bus speed) September 27, 1999

o 600 MHz Introduced (133 MHz bus speed) September


  • Coppermine - 0.18 µm process technology

* Introduced October 25, 1999
* Number of transistors 28.1 million
* 256 KB Advanced Transfer L2 Cache (Integrated)
* 242-pin Slot-1 SECC2 (Single Edge Contact cartridge 2) processor package, 370-pin FC-PGA
* System Bus Speed 100 MHz (E-models), 133 MHz (EB models)
* Slot 1, Socket 370
* Variants
o 500 MHz (100 MHz bus speed)
o 533 MHz
(100 MHz bus speed)
o 550 MHz (100 MHz bus speed)
o 600 MHz
(100 MHz bus speed)
o 600 MHz (100 MHz bus speed)
o 650 MHz (100 MHz bus speed) Introduced October 25, 1999
o 667 MHz Introduced October 25, 1999
o 700 MHz (100 MHz bus speed) Introduced October 25, 1999
o 733 MHz Introduced October 25, 1999
o 750 MHz (100 MHz bus speed) Introduced 10, 1999
o
800MHz (100 MHz bus speed) Introduced December 20, 1999
o 850 MHz (100 MHz bus speed)
o 866 MHz Int
roduced March 20, 2000
o 933 MHz Introduced May 24, 2000
o 1000 MHz Introduced March 8, 2000
o 1133 MHz (first version recalled, later re-released)


# Tualatin - 0.13 µm process technology

* Introduced July 2001
* Number of transistors 28.1 million
* 32 KB L1 cache
* 256 KB or 512 KB Advanced Transfer L2 cache (Integrated)
* 370-pin FC-PGA2 (Flip-chip pin grid array) package
* 133 MHz system bus speed
* Socket 370
* Family 6 model 11
* Variants
o 1133 MHz (256 KB L2)
o 1200 MHz(512 KB L2)
o 1266 MHz (512 KB L2)
o 1333 MHz(512 KB L2)
o 1400 MHz (512 KB L2)


4) Pentium 4/Pentium 4 HT

  • 0.18-0.065 µm process technology
  • Introduced November 20, 2000
  • L2 cache was 256-2048 KB Advanced Transfer Cache (Integrated)
  • System Bus Speed 400-800 MHz
  • Number of Transistors 42-70 million
  • Processor Package was PGA423, PGA478 ,LGA 775
  1. P4 Willamette
  2. P4 Northwood
  3. P4 Prescott
  4. P4 HT Northwood
  5. P4 HT Prescott
  6. P4 HT Cedar Mill

(Click "Spec" code in the chart to get full info about the Processor from Intel.com .
ex:SL8J7 = P4 HT 3.8GHZ processor)


SpecCPU
Speed
Proce-
ssor

Bus
Speed
Mfg
Tech

Cache
Size
PackageType........................................












SL8J73.80 GHz571
800 MHz 90 nm
1 MBLGA775

SL8PY3.80 GHz670
800 MHz90 nm
2 MBLGA775

SL7P23.80 GHzN/A
800 MHz90 nm
1 MBLGA775

SL7Z33.80 GHz670
800 MHz90 nm
2 MBLGA775

SL8Q93.80 GHz672
800 MHz90 nm
2 MBLGA775

SL82U3.80 GHz570J
800 MHz90 nm
1 MBLGA775

SL7KN3.60 GHz560
800 MHz90 nm
1 MBLGA775

SL96H3.60 GHz661
800 MHz65 nm
2 MBLGA775

SL8PZ3.60 GHz660
800 MHz90 nm
2 MBLGA775

SL7Z53.60 GHz660
800 MHz90 nm
2 MBLGA775

SL94V3.60 GHz661
800 MHz65 nm
2 MBLGA775

SL7L93.60 GHz560
800 MHz90 nm
1 MBLGA775

SL7J93.60 GHz560
800 MHz90 nm
1 MBLGA775

SL8UP3.60 GHz662
800 MHz90 nm
2 MBLGA775

SL8QB3.60 GHz662
800 MHz90 nm
2 MBLGA775

SL7NZ3.60 GHz560
800 MHz90 nm
1 MBLGA775

SL8WF3.60 GHz661
800 MHz65 nm
2 MBLGA775

SL8J63.60 GHz561
800 MHz90 nm
1 MBLGA775

SL84X3.60 GHz560J
800 MHz90 nm
1 MBLGA775

SL7Q23.60 GHz560J
800 MHz90 nm
1 MBLGA775

SL8Q53.40 GHz650
800 MHz90 nm
2 MBLGA775

SL8K43.40 GHzN/A
800 MHz90 nm
1 MB478 pin

SL7E63.40 GHzN/A
800 MHz90 nm
1 MB478 pin

SL7KD3.40 GHzN/A
800 MHz90 nm
1 MB478 pin

SL7KM3.40 GHz550
800 MHz90 nm
1 MBLGA775

SL8PS3.40 GHz551
800 MHz90 nm
1 MBLGA775

SL7B93.40 GHzN/A
800 MHz90 nm
1 MB478 pin

SL8333.40 GHz550J
800 MHz90 nm
1 MBLGA775

SL7PZ3.40 GHz550
800 MHz90 nm
1 MBLGA775

SL7PY3.40 GHz550J
800 MHz90 nm
1 MBLGA775

SL96J3.40 GHz651
800 MHz65 nm
2 MBLGA775

SL9C53.40 GHz551
800 MHz90 nm
1 MBLGA775

SL7PP3.40 GHzN/A
800 MHz90 nm
1 MB478 pin

SL7J83.40 GHz550
800 MHz90 nm
1 MBLGA775

SL8J53.40 GHz551
800 MHz90 nm
1 MBLGA775

SL9KE3.40 GHz651
800 MHz65 nm
2 MBLGA775

SL7Z73.40 GHz650
800 MHz90 nm
2 MBLGA775

SL8WG3.40 GHz651
800 MHz65 nm
2 MBLGA775

SL88L3.40 GHzN/A
800 MHz90 nm
1 MB478 pin

SL7933.40 GHzN/A
800 MHz0.13 micron
512KB478 pin

SL7AJ3.40E GHzN/A
800 MHz90 nm
1 MB478 pin

SL7L83.40 GHzN/A
800 MHz90 nm
1 MBLGA775

SL94W3.40 GHz651
800 MHz65 nm
2 MBLGA775

SL88K3.20E GHzN/A
800 MHz90 nm
1 MB478 pin

SL7KC3.20E GHzN/A
800 MHz90 nm
1 MB478 pin

SL7PX3.20 GHz540
800 MHz90 nm
1 MBLGA775

SL7LA3.20 GHzN/A
800 MHz90 nm
1 MBLGA775

SL7PN3.20E GHzN/A
800 MHz90 nm
1 MB478 pin

SL7PW3.20 GHz540J
800 MHz90 nm
1 MBLGA775

SL82Z3.20 GHz540J
800 MHz90 nm
1 MBLGA775

SL7KL3.20 GHz540
800 MHz90 nm
1 MBLGA775

SL7Z83.20 GHz640
800 MHz90 nm
2 MBLGA775

SL7L53.20 GHzN/A
800 MHz90 nm
1 MB478 pin

SL79M3.20E GHzN/A
800 MHz90 nm
1 MB478 pin

SL8WH3.20 GHz641
800 MHz65 nm
2 MBLGA775

SL94X3.20 GHz641
800 MHz65 nm
2 MBLGA775

SL8PR3.20 GHz541
800 MHz90 nm
1 MBLGA775

SL8Q63.20 GHz640
800 MHz90 nm
2 MBLGA775

SL7B83.20E GHzN/A
800 MHz90 nm
1 MB478 pin

SL6WG3.20 GHzN/A
800 MHz0.13 micron
512KB478 pin

SL9KF3.20 GHz641
800 MHz65 nm
2 MBLGA775

SL6WE3.20 GHzN/A
800 MHz0.13 micron
512KB478 pin

SL7923.20 GHzN/A
800 MHz0.13 micron
512KB478 pin

SL96K3.20 GHz641
800 MHz65 nm
2 MBLGA775

SL9C63.20 GHz541
800 MHz90 nm
1 MBLGA775

SL7J73.20 GHz540
800 MHz90 nm
1 MBLGA775

SL7E53.20E GHzN/A
800 MHz90 nm
1 MB478 pin

SL8K23.20E GHzN/A
800 MHz90 nm
1 MB478 pin

SL8J23.20 GHz541
800 MHz90 nm
1 MBLGA775

SL8ZZ3.06 GHz524
533 MHz90 nm
1 MBLGA775

SL6QC3.06 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL8JA3.06 GHz519K
533 MHz90 nm
1 MBLGA775

SL6S53.06 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL9CA3.06 GHz524
533 MHz90 nm
1 MBLGA775

SL6PG3.06 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6K73.06 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6JJ3.06 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL8PN3.06 GHz519K
533 MHz90 nm
1 MBLGA775

SL87L3.06 GHz519
533 MHz90 nm
1 MBLGA775

SL6SM3.06 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL7KB3E GHzN/A
800 MHz90 nm
1 MB478 pin

SL6WK3 GHzN/A
800 MHz0.13 micron
512KB478 pin

SL6WU3 GHzN/A
800 MHz0.13 micron
512KB478 pin

SL7PM3E GHzN/A
800 MHz90 nm
1 MB478 pin

SL7L43 GHzN/A
800 MHz90 nm
1 MB478 pin

SL7BK3 GHzN/A
800 MHz0.13 micron
512KB478 pin

SL7E43E GHzN/A
800 MHz90 nm
1 MB478 pin

SL7KK3 GHz530
800 MHz90 nm
1 MBLGA775

SL78Z3 GHzN/A
800 MHz0.13 micron
512KB478 pin

SL7J63 GHz530
800 MHz90 nm
1 MBLGA775

SL79L3E GHzN/A
800 MHz90 nm
1 MB478 pin

SL94Y3 GHz631
800 MHz65 nm
2 MBLGA775

SL88J3E GHzN/A
800 MHz90 nm
1 MB478 pin

SL96L3 GHz631
800 MHz65 nm
2 MBLGA775

SL82X3 GHz530J
800 MHz90 nm
1 MBLGA775

SL9CB3 GHz531
800 MHz90 nm
1 MBLGA775

SL8PQ3 GHz531
800 MHz90 nm
1 MBLGA775

SL8JZ3 GHzN/A
800 MHz90 nm
1 MB478 pin

SL8Q73 GHz630
800 MHz90 nm
2 MBLGA775

SL8WJ3 GHz631
800 MHz65 nm
2 MBLGA775

SL8HZ3 GHz531
800 MHz90 nm
1 MBLGA775

SL7Z93 GHz630
800 MHz90 nm
2 MBLGA775

SL9KG3 GHz631
800 MHz65 nm
2 MBLGA775

SL7PU3 GHz530J
800 MHz90 nm
1 MBLGA775

SL8ZY2.93 GHz517
533 MHz90 nm
1 MBLGA775

SL8PM2.93 GHz516
533 MHz90 nm
1 MBLGA775

SL8J92.93 GHz516
533 MHz90 nm
1 MBLGA775

SL7YV2.93 GHz515
533 MHz90 nm
1 MBLGA775

SL85V2.93 GHz515
533 MHz90 nm
1 MBLGA775

SL9CD2.93 GHz517
533 MHz90 nm
1 MBLGA775

SL8PP2.80 GHz521
800 MHz90 nm
1 MBLGA775

SL9CJ2.80 GHz511
533 MHz90 nm
1 MBLGA775

SL6WJ2.80 GHzN/A
800 MHz0.13 micron
512KB478 pin

SL7E32.80E GHzN/A
800 MHz90 nm
1 MB478 pin

SL7E22.80 GHzN/A
533 MHz90 nm
1 MB478 pin

SL7D82.80A GHzN/A
533 MHz90 nm
1 MB478 pin

SL8U42.80 GHz511
533 MHz90 nm
1 MBLGA775

SL6S42.80 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL79K2.80E GHzN/A
800 MHz90 nm
1 MB478 pin

SL6WT2.80 GHzN/A
800 MHz0.13 micron
512KB478 pin

SL6SL2.80 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL8U52.80 GHz511
533 MHz90 nm
1 MBLGA775

SL6Z52.80 GHzN/A
800 MHz0.13 micron
512KB478 pin

SL78Y2.80C GHzN/A
800 MHz0.13 micron
512KB478 pin

SL9CG2.80 GHz521
800 MHz90 nm
1 MBLGA775

SL7KH2.80 GHz520
533 MHz90 nm
1 MBLGA775

SL7KJ2.80 GHz520
800 MHz90 nm
1 MBLGA775

SL88H2.80E GHzN/A
800 MHz90 nm
1 MB478 pin

SL7KA2.80E GHzN/A
800 MHz90 nm
1 MB478 pin

SL8AB2.80 GHz620
800 MHz90 nm
2 MBLGA775

SL88G2.80 GHzN/A
533 MHz90 nm
1 MB478 pin

SL7PT2.80 GHz505
800 MHz90 nm
1 MBLGA775

SL6PF2.80 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL7PK2.80E GHzN/A
533 MHz90 nm
1 MB478 pin

SL6K62.80 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL82V2.80 GHz521
800 MHz90 nm
1 MBLGA775

SL7EY2.80 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL7PL2.80E GHzN/A
800 MHz90 nm
1 MB478 pin

SL6QB2.80 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL7PR2.80 GHz520J
800 MHz90 nm
1 MBLGA775

SL8JX2.80 GHzN/A
533 MHz90 nm
1 MB478 pin

SL6HL2.80 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL8HX2.80 GHz521
800 MHz90 nm
1 MBLGA775

SL7K92.80A GHzN/A
533 MHz90 nm
1 MB478 pin

SL7J52.80 GHz520
800 MHz90 nm
1 MBLGA775

SL7J42.80 GHz520
533 MHz90 nm
1 MBLGA775

SL6DX2.66 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6S32.66 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6EH2.66 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6QA2.66 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6SK2.66 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6PE2.66 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL8PL2.66 GHz506
533 MHz90 nm
1 MBLGA775

SL8J82.66 GHz506
533 MHz90 nm
1 MBLGA775

SL8B32.66 GHzN/A
533 MHz90 nm
1 MB478 pin

SL85U2.66 GHz505J
533 MHz90 nm
1 MBLGA775

SL7YU2.66 GHz505
533 MHz90 nm
1 MBLGA775

SL7E92.66 GHzN/A
533 MHz90 nm
1 MB478 pin

SL9CK2.66 GHz506
533 MHz90 nm
1 MBLGA775

SL6HB2.60 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6PP2.60 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6QR2.60 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6GU2.60 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6WS2.60 GHzN/A
800 MHz0.13 micron
512KB478 pin

SL6WH2.60 GHzN/A
800 MHz0.13 micron
512KB478 pin

SL6SB2.60 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6S22.53 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6Q92.53 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6EG2.53 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6EV2.53 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6SJ2.53 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6852.53 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6PD2.53 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6822.53 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6D82.53 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6DW2.53 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6PN2.50 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6GT2.50 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6EB2.50 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6SA2.50 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6QQ2.50 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL88F2.40 GHzN/A
533 MHz90 nm
1 MB478 pin

SL6PC2.40 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL67Z2.40 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6842.40 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL68T2.40 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL65R2.40 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL66T2.40 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL67R2.40 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6EF2.40 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6EU2.40 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6GS2.40 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6D72.40 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6DV2.40 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6E92.40 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6Z32.40 GHzN/A
800 MHz0.13 micron
512KB478 pin

SL7E82.40A GHzN/A
533 MHz90 nm
1 MB478 pin

SL6Q82.40 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL7FY2.40 GHzN/A
533 MHz90 nm
1 MB478 pin

SL6RZ2.40 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6QP2.40 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL79B2.40B GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6WF2.40 GHzN/A
800 MHz0.13 micron
512KB478 pin

SL6SR2.40 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6S92.40 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6WR2.40 GHzN/A
800 MHz0.13 micron
512KB478 pin

SL7YP2.40 GHzN/A
533 MHz90 nm
1 MB478 pin

SL6SH2.40 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6PM2.40 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6RY2.26 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL7D72.26 GHzN/A
533 MHz90 nm
512KB478 pin

SL6DU2.26 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6D62.26 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6832.26 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL67Y2.26 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6Q72.26 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6ET2.26 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6PB2.26 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL7V92.26 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL6EE2.26 GHzN/A
533 MHz0.13 micron
512KB478 pin

SL5ZU2.20 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6PL2.20 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6QN2.20 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL68S2.20 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6S82.20 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6GR2.20 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL5YS2.20 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6E82.20 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL66S2.20 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL5YR2 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL66R2 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6SP2 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL5ZT2 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL62Q2 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL68R2 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6E72 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL5SZ2 GHzN/A
400 MHz0.18 micron
256KB423 pin

SL6S72 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6QM2 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL5UH2 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL6PK2 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL5TQ2 GHzN/A
400 MHz0.18 micron
256KB423 pin

SL6GQ2 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL5TL2 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL5WH1.90 GHz N/A
400 MHz0.18 micron
256KB423 pin

SL5WG1.90 GHz N/A
400 MHz0.18 micron
256KB478 pin

SL5VN1.90 GHz N/A
400 MHz0.18 micron
256KB423 pin

SL6BF1.90 GHz N/A
400 MHz0.18 micron
256KB478 pin

SL67C1.90 GHz N/A
400 MHz0.18 micron
256KB478 pin

SL5VK1.90 GHz N/A
400 MHz0.18 micron
256KB478 pin

SL62P1.80 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL5UT1.80 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL5UM1.80 GHzN/A
400 MHz0.18 micron
256KB423 pin

SL5VJ1.80 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL5UV1.80 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL5VM1.80 GHzN/A
400 MHz0.18 micron
256KB423 pin

SL4X51.80 GHzN/A
400 MHz0.18 micron
256KB423 pin

SL5UK1.80 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL4WV1.80 GHzN/A
400 MHz0.18 micron
256KB423 pin

SL6QL1.80 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL68Q1.80 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL67B1.80 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL6PQ1.80 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6BE1.80 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL6E61.80 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6LA1.80 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL66Q1.80 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6S61.80 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL63X1.80 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL6SN1.80 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL62R1.80 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL5TP1.70 GHzN/A
400 MHz0.18 micron
256KB423 pin

SL5UG1.70 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL57V1.70 GHzN/A
400 MHz0.18 micron
256KB423 pin

SL5N91.70 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL59X1.70 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL5SY1.70 GHzN/A
400 MHz0.18 micron
256KB423 pin

SL5TK1.70 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL57W1.70 GHzN/A
400 MHz0.18 micron
256KB423 pin

SL6BD1.70 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL67A1.70 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL62Z1.70 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL6791.60 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL5VH1.60 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL5VL1.60 GHzN/A
400 MHz0.18 micron
256KB423 pin

SL4X41.60 GHzN/A
400 MHz0.18 micron
256KB423 pin

SL62S1.60 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL4WU1.60 GHzN/A
400 MHz0.18 micron
256KB423 pin

SL6681.60 GHzN/A
400 MHz0.13 micron
512KB478 pin

SL5UL1.60 GHzN/A
400 MHz0.18 micron
256KB423 pin

SL5US1.60 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL6BC1.60 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL5UJ1.60 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL5UW1.60 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL59V1.50 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL4X31.50 GHzN/A
400 MHz0.18 micron
256KB423 pin

SL62Y1.50 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL5UF1.50 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL4WT1.50 GHzN/A
400 MHz0.18 micron
256KB423 pin

SL5TN1.50 GHzN/A
400 MHz0.18 micron
256KB423 pin

SL5SX1.50 GHzN/A
400 MHz0.18 micron
256KB423 pin

SL6BA1.50 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL4SH1.50 GHzN/A
400 MHz0.18 micron
256KB423 pin

SL5TJ1.50 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL4TY1.50 GHzN/A
400 MHz0.18 micron
256KB423 pin

SL5N81.50 GHzN/A
400 MHz0.18 micron
256KB478 pin

SL4WS1.40 GHz N/A
400 MHz0.18 micron
256KB423 pin

SL4SG1.40 GHz N/A
400 MHz0.18 micron
256KB423 pin

SL5N71.40 GHz N/A
400 MHz0.18 micron
256KB478 pin

SL5TG1.40 GHz N/A
400 MHz0.18 micron
256KB478 pin

SL5UE1.40 GHz N/A
400 MHz0.18 micron
256KB478 pin

SL59U1.40 GHz N/A
400 MHz0.18 micron
256KB478 pin

SL4SC1.40 GHz N/A
400 MHz0.18 micron
256KB423 pin

SL4X21.40 GHz N/A
400 MHz0.18 micron
256KB423 pin

SL4QD1.30 GHzN/A
400 MHz0.18 micron
256KB423 pin

SL4SF1.30 GHzN/A
400 MHz0.18 micron
256KB423 pin

SL5GC1.30 GHzN/A
400 MHz0.18 micron
256KB423 pin

SL5FW1.30 GHzN/A
400 MHz0.18 micron
256KB423 pin


5) Pentium 4 Extreme Edition

  • Introduced September 2003
  • P4EE EE= "Extreme Edition"
  • Built from the Xeon's "Gallatin" core, but with 2 MB cache-
  1. Gallatin
  2. Prescott-2M


sSpecCPU SpeedProc-
essor
CoresBus SpeedMfg TechSte-
pping
Cache SizePackage.................... ..........
SL7Z43.73 GHzN/A11066 MHz90 nmN02 MBLGA77504B
SL7NF3.46 GHzN/A11066 MHz0.13 micronM0512 KBLGA77504B
SL7RT3.46 GHzN/A11066 MHz0.13 micronM02 MBLGA77504B
SL7CH3.40 GHzN/A1800 MHz0.13 micronM02 MB478 pinN/A
SL7GD3.40 GHzN/A1800 MHz0.13 micronM02 MBLGA775N/A
SL7RR3.40 GHzN/A1800 MHz0.13 micronM02 MBLGA775N/A
SL7AA3.20 GHzN/A1800 MHz0.13 micronM0512 KB478 pinN/A

(Click "Spec" code in the chart to get full info about the Processor from Intel.com .
ex:SL8J7 = P4 HT 3.8GHZ processor)


6)Pentium Dual Core

  • Allendale - 65 nm process technology

* Desktop CPU (SMP support restricted to 2 CPUs)
* Two CPUs on one die
* Introduced January 21, 2007
* SSSE3 SIMD instructions
* Number of Transistors 167 Million
* LaGrande Technology, enhanced security hardware extensions
* Execute Disable Bit
* EIST (Enhanced Intel SpeedStep Technology)
* iAMT2 (Intel Active Management Technology), remotely manage computers
* LGA775

  • Wolfdale 45nm process technology
* released august 2008
* Two CPUs on one die
* 45nm tech
* 2MB cache L2
* SSSE 4.1
* Execute Disable Bit
* EIST (Enhanced Intel SpeedStep Technology)
* iAMT2 (Intel Active Management Technology), remotely manage computers
* LGA775




SpecCPU
Speed
Proc-
essor
C#Bus SpeedMfg
Tech
Step.
Cache
size
Package...........................................
SLAY72.5 GHzE52002800 MHz45 nmM02 MBLGA77506
SLA8W2.40 GHzE22202800 MHz65 nmM01 MBLGA77506
SLA8X2.20 GHzE22002800 MHz65 nmM0
1 MBLGA77506
SLA8Y2.00GHzE21802800 MHz65 nmM01 MBLGA77506
SLA9Z1.80 GHzE21602800 MHz65 nmG01 MBLGA77506
SLA3H1.80 GHzE21602800 MHz65 nmL21 MBLGA77506
SLA8Z1.80 GHzE21602800 MHz65 nmM01 MBLGA77506
SLALS1.60 GHzE21402800 MHz65 nmG01 MBLGA77506
SLA3J1.60 GHzE21402800 MHz65 nmL21 MBLGA77506
SLA931.60 GHzE21402800 MHz65 nmM01 MBLGA77506

(Click "Spec" code in the chart to get full info about the Processor from Intel.com .
ex:SL8J7 = P4 HT 3.8GHZ processor)

7) Pentium D


* Dual Core Microproccessor

* No Hyper-Threading

* 800(4x200) MHz front side bus

  • Smithfield - 90 nm process technology (2.66–3.2 GHz)

o Introduced May 26, 2005
o 2.66–3.2 GHz (model numbers 805-840)
o Number of Transistors 230 million
o 1 MB x 2 (non-shared, 2 MB total) L2 cache
o Cache coherency between cores requires communication over the FSB
o Performance increase of 60% over similarly clocked Prescott
o 2.66 GHz (533 MHz FSB) Pentium D 805 introduced December 2005
o Contains 2x Prescott dies in one package

  • Presler - 65 nm process technology (2.8–3.6 GHz)
o Introduced January 16, 2006
o 2.8–3.6 GHz (model numbers 915-960)
o Number of Transistors 376 million
o 2 MB x 2 (non-shared, 4 MB total) L2 cache
o Contains 2x Cedar Mill dies in one package



sSpecCPU
Speed
Proc-
essor
C#Bus
Speed
Mfg
Tech
StepCache
Package...........................................
SL9AP3.60 GHz9602800 MHz65 nmC14MB(2x2)LGA77505B
SL9K73.60 GHz9602800 MHz65 nmD04MB(2x2)LGA77505A
SL95V3.40 GHz9502800 MHz65 nmC14MB(2x2)LGA77505A
SL94P3.40 GHz9502800 MHz65 nmB14MB(2x2)LGA77505B
SL9K83.40 GHz9502800 MHz65 nmD04MBLGA77505A
SL9QQ3.40 GHz9452800 MHz65 nmD04MB(2x2)LGA77505A
SL9QB3.40 GHz9452800 MHz65 nmC14MB(2x2)LGA77505A
SL95W3.20 GHz9402800 MHz65 nmC14MB(2x2)LGA77505A
SL94Q3.20 GHz9402800 MHz65 nmB14MB(2x2)LGA77505B
SL8CM3.20 GHz8402800 MHz90 nmB02MBLGA77505B
SL88R3.20 GHz8402800 MHz90 nmA02MBLGA77505B
SL9QR3.20 GHz9352800 MHz65 nmD04MBLGA77505A
SL88S3 GHz8302800 MHz90 nmA02MBLGA77505B
SL8CN3 GHz8302800 MHz90 nmB02MBLGA77505B
SL8WR3 GHz9302800 MHz65 nmB14MBLGA77505A
SL9KA3 GHz9252800 MHz65 nmD04MB(2x2)LGA77505A
SL95X3 GHz9302800 MHz65 nmC14MB(2x2)LGA77505A
SL9D93 GHz9252800 MHz65 nmC14MB(2x2)LGA77505A
SL94R3 GHz9302800 MHz65 nmB14MB(2x2)LGA77505A
SL94S2.80 GHz9202800 MHz65 nmB14MB(2x2)LGA77505A
SL88T2.80 GHz8202800 MHz90 nmA02MBLGA77505A
SL9DA2.80 GHz9152800 MHz65 nmC14MB(2x2)LGA77505A
SL9KB2.80 GHz9152800 MHz65 nmD04MB(2x2)LGA77505A
SL8CP2.80 GHz8202800 MHz90 nmB02MBLGA77505A
SL8WS2.80 GHz9202800 MHz65 nmB14MBLGA77505A
SL8ZH2.66 GHz8052533 MHz90 nmB02MBLGA77505A



8) Pentium Extreme Edition

* Dual-core microprocessor
* Enabled Hyper-Threading
* 800(4x200)-1066(2x266) MHz front side bus

  • Smithfield - 90 nm process technology (3.2 GHz)
  • Presler - 65 nm process technology (3.46, 3.73)

sSpecCPU
Speed
Proc-
essor
CoresBus
Speed
Mfg
Tech
StepCache
Size
Package............................................
SL9AN3.73 GHz96521066 MHz65 nmC14 MBLGA77505B
SL8WM3.46 GHz95521066 MHz65 nmB14 MBLGA77505B
SL94N3.46 GHz95521066 MHz65 nmB14 MB
LGA77505B
SL8FK3.20 GHz8402800 MHz90 nmA02 MBLGA77505B


9) Intel Core 2 Duo

  • Conroe - 65 nm process technology

* Desktop CPU (SMP support restricted to 2 CPUs)
* Two cores on one die
* Introduced July 27, 2006
* SSSE3 SIMD instructions
* Number of Transistors 291 Million
* Intel Virtualization Technology, multiple OS support
* LaGrande Technology, enhanced security hardware extensions
* Execute Disable Bit
* EIST (Enhanced Intel SpeedStep Technology)
* iAMT2 (Intel Active Management Technology), remotely manage computers
* LGA775

  • Allendale - 65 nm process technology

* Desktop CPU (SMP support restricted to 2 CPUs)
* Two CPUs on one die
* Introduced January 21, 2007
* SSSE3 SIMD instructions
* Number of Transistors 167 Million
* LaGrande Technology, enhanced security hardware extensions
* Execute Disable Bit
* EIST (Enhanced Intel SpeedStep Technology)
* iAMT2 (Intel Active Management Technology), remotely manage computers
* LGA775

  • Wolfdale - 45 nm process technology

* Die shrink of Conroe
* Same features as Conroe with the addition of:-
o 50% more cache, 6 MB as opposed to 4 MB
o Intel Trusted Execution Technology
o SSE4 SIMD instructions
* Number of Transistors 410 Million



sSpecCPU
Speed
Proc-
essor
CoresBus
Speed
Mfg
Tech
StepCache
Size
Package............................................
SLB9L3.33 GHzE860021333 MHz45 nmE06 MBLGA77506
SLB9K3.16 GHzE850021333 MHz45 nmE06 MBLGA77506
SLAPK3.16 GHzE850021333 MHz45 nmC06 MBLGA77506
SLAPL3 GHzE840021333 MHz45 nmC06 MBLGA77506
SLA9U3 GHzE685021333 MHz65 nmG04 MBLGA77506
SLB9J3 GHzE840021333 MHz45 nmE06 MBLGA77506
SLAPJ2.83 GHzE830021333 MHz45 nmC06 MBLGA77506
SLA9V2.66 GHzE675021333 MHz65 nmG04 MBLGA77506
SL9S72.66 GHzE670021066 MHz65 nmB24 MBLGA77506
SL9ZF2.66 GHzE670021066 MHz65 nmB24 MBLGA77506
SLB9X2.66 GHzE730021066 MHz45 nmM03 MBLGA77506
SLAPB2.66 GHzE730021066 MHz45 nmM03 MBLGA77506
SLAQR2.66 GHzE819021333 MHz45 nmC06 MBLGA77506
SLAPP2.66 GHzE820021333 MHz45 nmC06 MBLGA77506
SLALT2.60 GHzE47002800 MHz65 nmG02 MBLGA77506
SLAVN2.53 GHzE720021066 MHz45 nmM03 MBLGA77506
SLAPC2.53 GHzE720021066 MHz45 nmM03 MBLGA77506
SLA942.40 GHzE46002800 MHz65 nmM02 MBLGA77506
SL9ZL2.40 GHzE660021066 MHz65 nmB24 MBLGA77506
SL9S82.40 GHzE660021066 MHz65 nmB24 MBLGA77506
SLA9X2.33 GHzE655021333 MHz65 nmG04 MBLGA77506
SLAA52.33 GHzE654021333 MHz65 nmG04 MBLGA77506
SLA952.20 GHzE45002800 MHz65 nmM02 MBLGA77506
SL9T92.13 GHzE640021066 MHz65 nmL22 MBLGA77506
SL9S92.13 GHzE640021066 MHz65 nmB22 MBLGA77506
SLA4T2.13 GHzE642021066 MHz65 nmB24 MBLGA77506
SLA982 GHzE44002800 MHz65 nmM02 MBLGA77506
SLA3F2 GHzE44002800 MHz65 nmL22 MBLGA77506
SL9SA1.86 GHzE630021066 MHz65 nmB22 MBLGA77506
SL9TA1.86 GHzE630021066 MHz65 nmL22 MBLGA77506
SLA4U1.86 GHzE632021066 MHz65 nmB24 MBLGA77506
SL9TB1.80 GHzE43002800 MHz65 nmL22 MBLGA77506


10) Intel Core 2 Quad

  • Kentsfield - 65 nm process technology

* Two dual-core cpu dies in one package.
* Desktop CPU Quad Core (SMP support restricted to 4 CPUs)
* Introduced December 13, 2006
* same features as Conroe but with 4 CPU Cores
* Number of Transistors 586 Million
* Socket 775

  • Yorkfield - 45 nm process technology

* Quad core CPU
* Die shrink of Kentsfield
* Contains 2x Wolfdale dual core dies in one package
* Same features as Wolfdale
* Number of Transistors 820 Million


sSpecCPU
Speed
Proc-
essor
Co-
res
Bus
Speed
Mfg
Tech
StepCache
Size
Package..........................................
SLB8W3 GHzQ965041333 MHz45 nmE012 MBLGA77505A
SLB8V2.83 GHzQ955041333 MHz45 nmE012 MBLGA77505A
SLAWQ2.83 GHzQ955041333 MHz45 nmC112 MBLGA77505A
SLACQ2.66 GHzQ670041066 MHz65 nmG08 MBLGA77505A
SLAWR2.66 GHzQ945041333 MHz45 nmC112 MBLGA77505A
SLB6B2.66 GHzQ940041333 MHz45 nmR06 MBLGA77505A
SLAWE2.50 GHzQ930041333 MHz45 nmM16 MBLGA77505A
SLACR2.40 GHzQ660041066 MHz65 nmG08 MBLGA77505A
SL9UM2.40 GHzQ660041066 MHz65 nmB38 MBLGA77505B
SLG9S2.33 GHzQ820041333 MHz45 nmR04 MBLGA77505A
SLB5M2.33 GHzQ820041333 MHz45 nmM14 MBLGA77505A


11)Intel Core 2 Extreme

  • Conroe XE - 65 nm process technology

* Desktop Extreme Edition CPU (SMP support restricted to 2 CPUs)
* Introduced July 27, 2006
* same features as Conroe
* LGA775

  • Kentsfield XE - 65 nm process technology

* Two dual-core cpu dies in one package.
* Desktop CPU Quad Core (SMP support restricted to 4 CPUs)
* Introduced December 13, 2006
* same features as Conroe but with 4 CPU Cores
* Number of Transistors 586 Million
* Socket 775

  • Yorkfield - 45 nm process technology

* Quad core CPU
* Die shrink of Kentsfield
* Contains 2x Wolfdale dual core dies in one package
* Same features as Wolfdale
* Number of Transistors 820 Million



SpecCPU
Speed
Proc-
cessor
Co-
res
Bus
Speed
Mfg
Tech

Cache
Size
Package.......................................
SLAWM3.20 GHzQX977041600 MHz45 nm
12 MBLGA77505B
SLANY3.20 GHzQX977541600 MHz45 nm
12 MBLGA771N/A
SLAFN3 GHzQX685041333 MHz65 nm
8 MBLGA77505B
SLAN33 GHzQX965041333 MHz45 nm
12 MBLGA77505B
SLAWN3 GHzQX965041333 MHz45 nm
12 MBLGA77505B
SL9UK2.93 GHzQX680041066 MHz65 nm
8 MBLGA775N/A
SL9S52.93 GHzX680021066 MHz65 nm
4 MBLGA77505B
SLACP2.93 GHzQX680041066 MHz65 nm
8 MBLGA77505B
SL9UL2.66 GHzQX670041066 MHz65 nm
8 MBLGA77505B



12) Intel Core i7/Core i7 Extreme


Model Process Cores/ Threads Speed Price Cache Memory Contoller Bus Interface TDP Socket Release date
Core i7
965 Extreme Edition
45nm
4/8
3.2
GHz
$999
256 KB L2/core
8 MB shared L3
Triple channel DDR3
800
/1066
/1333 MHz
1x 6.4 GT/s QuickPath 130W
LGA1366
Oct 2008
Core i7
930
2.93
GHz
$562 1x 4.8 GT/s QuickPath
Core i7
800
2.66
GHz
$284



Core i7

The Core i7 brand refers to an upcoming range of Intel's consumer 64-bit quad-core CPUs with the x86-64 instruction set, based on the Intel Nehalem microarchitecture. These chips will also feature simultaneous multithreading, which will allow the quad core chips to work on eight threads simultaneously.According to an Intel spokesperson, the Core i7 identifier applies to the initial family of processors, Bloomfield, due to be launched in Q4 2008. According to Intel representatives, the moniker Core i7 does not have a deeper meaning.(wiki)
Products based on the new microarchitecture will deliver high performance and energy efficiency. This "best of both worlds" approach is expected to extend Intel's processor leadership in future mobile, desktop and server market segments.

Launch

Originally scheduled to launch in November or December this year, Intel's Nehalem-based Bloomfield processors will now launch in September along with X58 chipsets, sources at motherboard makers have revealed.However, the sources pointed out that CPUs and motherboards will not officially appear in the channel until early October.

Performance

A 2.93 GHz Core i7 900 system has been used to run a 3DMark Vantage benchmark and gave a CPU score of 17,966.The 2.66 GHz Core i7 800 scores 16,294. A 2.4 GHz Core 2 Duo E6600 scores 4,300.
AnandTech tested the Intel QuickPath Interconnect (4.8 GT/s version) and found the copy bandwidth using triple-channel 1066 MHz DDR3 was 12.0 GB/s. A 3.0 GHz Core 2 Quad system using dual-channel 1066 MHz DDR3 achieved 6.9 GB/s.

Overclocking

Overclocking will be possible with the 800 and 900 series and a motherboard equipped with the X58 chipset. The Lynnfield and Havendale processors will use a PCH removing the need for a northbridge chipset and requiring a different motherboard design.

QuickPath to replace FSB(Front Side Bus)

With X58,QuickPath to replace FSB. Those who are accustomed to overclocking their motherboards using the FSB, will have to start over and learn the new system. Similar to AMD’s HyperTransport, the QuickPath architecture will feature an integrated memory controller on the CPU and provide direct links between the CPU and system memory.

X58 chipset Motherboard(Codename 'Tylersburg')

Intel will launch the X58 chipset with the same ICH-10 family of southbridges currently used on its P45 platform.ICH-10 supplies up to four PCI Express x16 paths,of which two, are PCI Express 2.0 paths. Other possible combinations are: one x16 path, two x16 paths, four x8 paths, and one 16 path and two x8 paths.Because of QuickPath however, we’re able to realize far better performance with wide bandwidth and very low latency. According to Intel, Nehalem will initially come with a 20-bit wide 25.6 GB/sec. QuickPath link, which gives a theoretical 2x performance increase in bandwidth over the 1600MHz FSB currently available on the X48 platform.
Memory support will come in the form of DDR3 with support for 800MHz, 1066MHz and 1333MHz frequencies initially. Total bandwidth will be 32GB/sec. with support for up to 24GB of total system memory initially. X58 motherboards will provide up to 6 slots of memory but will require that the first slot (DIMM0) be populated.Sources indicated that Intel will release Bloomfield, the first of the Nehalem family at 3.2GHz, 2.93GHz and 2.66GHz and on an LGA1366-pin platform.


13) Intel Sandybridge (microarchitecture)

Sandybridge is the code name for a processor that is being developed by Intel and is the planned successor to Nehalem. Intel is already into the development process for Sandy Bridge. Sandy Bridge uses the 32 nm manufacturing methods from (formerly known as WestmereNehalem-C) and applies it to the new Sandybridge microarchitecture. The former codename for this core was Gesher (means 'bridge' in Hebrew), but that codename was abandoned on 17 April 2007 because a political party in Israel is also named Gesher, as mentioned in Justin Rattner's keynote at IDF Spring 2007. Intel's plans are to introduce new microarchitectures every two years, so this processor should debut in 2010.It should have 8 cores on the same die, an L2 cache of 512 KB per heart and a L3 cache of 16 MB One of the main characteristics Sandy Bridge will be adding the game 'Instruction AVX (Advanced Vectors Extensions), formerly known as VSSE.

Architecture

Sandy Bridge's specifications are reported to be as follows, according to a presentation made by Intel in December 2006:These specifications share similarities with the cancelled Gulftown processor.

* 4 GHz clock speed.
* 4 to 8 out-of-order cores.
* Without SSE: 8 DP GFLOPS/core (2 DP FP/clock), 32-64 DP GFLOPS/processor.
* With SSE: 28 DP GFLOPS/core (7 DP FP/clock), 112-224 DP GFLOPS/processor.
* 32 KB L1 cache/core, (3 clocks).
* 512 KB L2 cache/core, (9 clocks).
* 2-3 MB L3 cache/core (8-24 MB total) (33 clocks), most likely pooled and dynamically allocated among the cores.
* 64 bytes cache line width.
* 256 bytes/cycle Ring bus bandwidth. The ring bus connects the cores.
* 0-512 MB GDDR / fast DRAM.
* 64 GB/s GDDR / fast DRAM memory bandwidth.
* 17 GB/s memory bandwidth per QuickPath link with 50 ns latency.


Features

* Sandy Bridge will focus on power efficiency.
* Performance will be increased without a core size increase (similar to the Netburst to Core transition).
* Due to the small 32 nm process, the floating point unit is relatively small compared to the rest of the core.
* Dynamic Turbo allows the CPU power to exceed the TDP value when the rest of the platform is relatively cool. The frequency gain can be up to 37% for one minute, and over 20% in most cases.
* Nehalem may stay at the server platform while Sandy Bridge is released for the mobile segments, which would split the markets into two CPU lines.
* Sandy Bridge's CPU and GPU are likely to be on one die (unlike the two-die approach of Nehalem).
* Because of the high-performing CPU and off-chip components, it may be necessary to improve bus interconnects.
* The Sandy Bridge microarchitecture is also said to focus on the connections of the processor core.



14) Haswell (microarchitecture)

Haswell is the code name for a processor that is being developed by Intel and is the planned successor to Sandy Bridge. Haswell will be designed for the 22 nm manufacturing process and is planned for a commercial release in 2012. Haswell should be the first Intel CPU to implement FMA (Fused Multiply-Add) instructions.Haswell's design is in the early stages of development. Like Nehalem, Haswell is being developed by Intel's Oregon team rather than by Intel's Israel Development Center like Core and Sandy Bridge.

Architecture


Haswell is expected to have these features.

* 22 nm process
* 8 cores by default
* Entirely new cache design
* Revolutionary power saving systems
* Possible on-package vector coprocessors
* The addition of the FMA(Fused Multiply-Add) instruction set