PML50002201AC [INTEL]
Microprocessor, 32-Bit, 500MHz, CMOS, MMC-2;型号: | PML50002201AC |
厂家: | INTEL |
描述: | Microprocessor, 32-Bit, 500MHz, CMOS, MMC-2 时钟 外围集成电路 |
文件: | 总64页 (文件大小:778K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
Pentium III Processor Mobile Module:
Mobile Module Connector 2 (MMC-2)
Datasheet
Product Features
■ Mobile Pentium III processor at speeds of
■ Intel 82443BX Host Bridge system
450 MHz and 500 MHz
controller
■ On-die, primary 16-K Instruction cache and
—DRAM controller supports 3.3-V
SDRAM at 100 MHz
16-K Write Back Data cache
■ On-die, 256-K L2 cache
—Supports PCI CLKRUN# protocol
—Eight-way set associative
—SDRAM clock enable support and self-
refresh of SDRAM during Suspend
mode
—Runs at the speed of the processor core
■ Fully compatible with previous Intel
mobile microprocessors
—PCI bus control 3.3V only, PCI
Specification Revision 2.1 compliant
—Binary compatible with all applications
—Support for MMX technology
■ Supports streaming SIMD
■ Supports single AGP 66-MHz, 3.3-V
device
■ Two-piece TTP thermal transfer plate
■ Power management features that provide
(TTP) for heat dissipation
low-power dissipation
—Quick Start mode
—Deep Sleep mode
—The CPU TTP is made of nickel-plated
copper
—The BX TTP is made of aluminum
■ Integrated math co-processor
■ Pentium III processor core voltage
regulation supports input voltages from
7.5V to 21.0V DC
■ Integrated Active Thermal Feedback (ATF)
system
■ Programmable trip point interrupt or poll
—Above 80% peak efficiency
—Integrated VR solution
mode for temperature reading
245304-004
Information in this document is provided in connection with Intel products. No license, express or implied, by estoppel or otherwise, to any intellectual
property rights is granted by this document. Except as provided in Intel’s Terms and Conditions of Sale for such products, Intel assumes no liability
whatsoever, and Intel disclaims any express or implied warranty, relating to sale and/or use of Intel products including liability or warranties relating to
fitness for a particular purpose, merchantability, or infringement of any patent, copyright or other intellectual property right. Intel products are not
intended for use in medical, life saving, or life sustaining applications.
Intel may make changes to specifications and product descriptions at any time, without notice.
Designers must not rely on the absence or characteristics of any features or instructions marked "reserved" or "undefined." Intel reserves these for
future definition and shall have no responsibility whatsoever for conflicts or incompatibilities arising from future changes to them.
The Pentium III processor mobile module may contain design defects or errors known as errata which may cause the product to deviate from
published specifications. Current characterized errata are available on request.
MPEG is an international standard for video compression/decompression promoted by ISO. Implementations of MPEG CODECs, or MPEG enabled
platforms may require licenses from various entities, including Intel Corporation.
Contact your local Intel sales office or your distributor to obtain the latest specifications and before placing your product order.
Copies of documents which have an ordering number and are referenced in this document, or other Intel literature may be obtained by calling 1-800-
548-4725 or by visiting Intel’s website at http://www.intel.com.
Copyright © Intel Corporation, 1999, 2000
*Other brands and names are the property of their respective owners.
Datasheet
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Pentium III Processor Mobile Module MMC-2
Contents
1.0
Introduction.........................................................................................................................1
1.1 References............................................................................................................1
2.0
3.0
Architecture Overview ........................................................................................................2
Signal Information ..............................................................................................................4
3.1
Signal Definitions...................................................................................................4
3.1.1 Signal List.................................................................................................5
3.1.2 Memory Signal Description ......................................................................6
3.1.3 AGP Signals.............................................................................................7
3.1.4 PCI Signals...............................................................................................9
3.1.5 Processor and PIIX4E/M Sideband Signals...........................................11
3.1.6 Power Management Signals ..................................................................12
3.1.7 Clock Signals..........................................................................................13
3.1.8 Voltage Signals ......................................................................................14
3.1.9 ITP and JTAG Pins.................................................................................15
3.1.10 Miscellaneous Pins.................................................................................15
Connector Pin Assignments................................................................................16
Pin and Pad Assignments ...................................................................................18
3.2
3.3
4.0
Functional Description......................................................................................................20
4.1
4.2
4.3
Pentium III Processor Mobile Module MMC-2.....................................................20
L2 Cache.............................................................................................................20
The 82443BX Host Bridge System Controller.....................................................20
4.3.1 Memory Organization.............................................................................20
4.3.2 Reset Strap Options...............................................................................21
4.3.3 PCI Interface ..........................................................................................21
4.3.4 AGP Interface.........................................................................................22
Power Management ............................................................................................22
4.4.1 Clock Control Architecture......................................................................22
4.4.1.1 Normal State .............................................................................24
4.4.1.2 Auto Halt State ..........................................................................24
4.4.1.3 Stop Grant State........................................................................25
4.4.1.4 Quick Start State .......................................................................25
4.4.1.5 HALT/Grant Snoop State ..........................................................26
4.4.1.6 Sleep State................................................................................26
4.4.1.7 Deep Sleep State ......................................................................26
Power Consumption in Power Management Mode.............................................27
4.4
4.5
5.0
Electrical Specifications....................................................................................................28
5.1
System Bus Clock Signal Quality Specifications.................................................28
5.1.1 BCLK DC Specifications.........................................................................28
5.1.2 BCLK AC Specifications.........................................................................28
System Power Requirements..............................................................................30
Processor Core Voltage Regulation....................................................................30
5.3.1 Voltage Regulator Efficiency ..................................................................30
5.3.2 Voltage Regulator Control......................................................................32
5.2
5.3
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Pentium III Processor Mobile Module MMC-2
5.3.3 Power Planes: Bulk Capacitance Requirements....................................34
5.3.4 System Power Supply Protection Guidelines.........................................36
5.3.4.1 DC Power System Protection....................................................36
5.3.4.2 V_DC Power Supply..................................................................37
5.3.4.3 Overcurrent Protection ..............................................................37
5.3.4.4 Current Limit Shift Point ............................................................39
5.3.4.5 Slew Rate Control .....................................................................41
5.3.4.6 Undervoltage Lockout ...............................................................43
5.3.4.7 Overvoltage Lockout .................................................................44
Active Thermal Feedback ...................................................................................48
Thermal Sensor Configuration Register..............................................................48
5.4
5.5
6.0
Mechanical Specification..................................................................................................49
6.1
Module Dimensions.............................................................................................49
6.1.1 Pin 1 Location of the MMC-2 Connector................................................49
6.1.2 Printed Circuit Board..............................................................................50
6.1.3 Height Restrictions.................................................................................51
Thermal Transfer Plate .......................................................................................51
Module Physical Support ....................................................................................53
6.3.1 Module Mounting Requirements ............................................................53
6.3.2 Module Weight .......................................................................................54
6.2
6.3
7.0
Thermal Specification.......................................................................................................55
7.1 Thermal Design Power........................................................................................55
8.0
9.0
Labeling Information.........................................................................................................56
Environmental Standards.................................................................................................58
Figures
1
2
3
4
5
6
7
8
Pentium III Processor Mobile Module Block Diagram...........................................3
MMC-2 Connector Pad Footprint ........................................................................19
Clock Control States ...........................................................................................24
BCLK Waveform at the Processor Core Pins .....................................................29
VR Efficiency Chart ............................................................................................31
Power Sequence Timing.....................................................................................34
V_DC Ripple Current ..........................................................................................36
V_DC Power System Protection Block Diagram.................................................37
Overcurrent Protection Circuit.............................................................................38
Current Shift Model .............................................................................................39
Undervoltage Lockout .........................................................................................43
Undervoltage Lockout Model ..............................................................................44
Overvoltage Lockout ...........................................................................................45
Overvoltage Lockout Model ................................................................................45
Recommended Power Supply Protection Circuit for the System Electronics .....47
Simulation of V_DC Voltage Skew......................................................................47
Board Dimensions and MMC-2 Connector Orientation.......................................49
Board Dimensions and MMC-2 Connector—Pin 1 Orientation...........................50
9
10
11
12
13
14
15
16
17
18
iv
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Pentium III Processor Mobile Module MMC-2
19
20
21
22
23
24
25
Printed Circuit Board Thickness..........................................................................50
Keep-out Zone.....................................................................................................51
82443BX Thermal Transfer Plate (Reference Only) ..........................................52
82443BX Thermal Transfer Plate Detail..............................................................52
CPU Thermal Transfer Plate (Reference Only)...................................................53
Standoff Holes, Board Edge Clearance, and EMI Containment Ring .................54
Product Tracking Code........................................................................................57
Tables
1
2
3
4
5
6
7
8
Connector Signal Summary ..................................................................................4
Memory Signal Descriptions..................................................................................6
AGP Signal Descriptions.......................................................................................7
PCI Signal Descriptions.........................................................................................9
Processor and PIIX4E/M Sideband Signal Descriptions.....................................11
Power Management Signal Descriptions ............................................................12
Clock Signal Descriptions....................................................................................13
Voltage Descriptions ...........................................................................................14
ITP and JTAG Pins..............................................................................................15
Miscellaneous Pin Descriptions...........................................................................15
Connector Pin Assignment..................................................................................16
Connector Specifications.....................................................................................19
Configuration Straps for the 82443BX Host Bridge System Controller ...............21
Clock State Characteristics .................................................................................23
Power Consumption Values I..............................................................................27
Power Consumption Values II.............................................................................27
BCLK DC Specifications......................................................................................28
BCLK AC Specifications at the Processor Core Pins..........................................28
BCLK Signal Quality AC Specifications at the Processor Core...........................29
System Power Requirements..............................................................................30
Vcore Power Conversion Efficiency ...................................................................31
Voltage Signal Definitions and Sequences .........................................................32
VR_ON In-rush Current.......................................................................................33
Bulk Capacitance Requirements.........................................................................35
Thermal Sensor SMBus Address........................................................................48
Thermal Sensor Configuration Register..............................................................48
Thermal Design Power Specification ..................................................................55
Environmental Standards....................................................................................58
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
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Pentium III Processor Mobile Module MMC-2
Revision History
Date
Revision
Updates
October 1999
February 2000
1.0
2.0
Initial Release
Revision 2.0 contains the following updates:
•All PIIX4M references have changed to PIIX4E/M because both parts may
be used
•Added Section 4.5, which now contains the power consumption values in
power management modes
•Updated the entire Sections of 5.1 and 5.2 for clarity
•Section 5.3.4 was updated for accuracy and clarity
•The VR efficiency values were updated in Table 20 and Figure 5. Previously,
the values were shown at 1.35V
•Updated Figure 6. An Intel SpeedStep technology signal was removed
•Updated Table 24 to be consistent with the schematics
•Added a note in Figure 17 for clarification
•Figure 22 was added for additional thermal transfer plate detail
•Specification clarifications were made to Section 6.2 and Section 6.3.1
April 2000
3.0
Revision 3.0 contains the following updates:
•Added Table 16, “Power Consumption Values II”, which contains power
management data on conversion modules and B-step modules
•In Table 19, “BCLK Signal Quality AC Specifications at the Processor Core”
note 3 was updated for clarification
•Added maximum and minimum designators to Figure 4, “BCLK Waveform at
the Processor Core Pins” for clarity
•Rewrote Section 5.3.3, “Power Planes: Bulk Capacitance Requirements” for
clarity
September 2000
4.0
Revision 4.0 contains the following updates:
•Added new product tracking numbers to Table 16.
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Pentium III Processor Mobile Module MMC-2
1.0
Introduction
This document provides the technical specifications for integrating the Intel Pentium III processor
mobile module connector 2 (MMC-2) into the latest notebook systems for today’s notebook
market.
Building around this design gives the system manufacturer these advantages:
• Avoids complexities associated with designing high-speed processor core logic boards.
• Provides an upgrade path from previous Intel mobile modules using a standard interface.
1.1
References
Refer to the following documents for additional information relating to the Pentium III processor
mobile module.
Mobile Pentium III Processor Datasheet
Intel 440BX AGPSet: 82443BX Host Bridge/Controller Datasheet (Order Number: 290633-001)
82371AB PCI-to-ISA/IDE Xcelerator (PIIX4) (Order Number: 290562-001)
Intel 82371MB (PIIX4E/M) Specification Update*
CK97 Clock Synthesizer/Driver Specification (OR-1089)
Intel Pentium III Processor Mobile Module MMC-2 Simulation and Validation Kit Rev. 2.0 (OR-
1781)
Intel Pentium III Processor Mobile Module System Electronics 100-MHz Layout Guidelines Rev.
1.0 (OR-1780)
Mobile Pentium III Processor/440BX AGPset Recommended Design and Debug Practices
(RDDP-A) 100 MHz Rev. 2.0 (SC-2760)
66/100MHz PC SDRAM Unbuffered SO-DIMM Specification Rev 1.0*
Intel Mobile Module Design Guide (AP-590)
Pentium® II Processor Mobile Module MMC-2 Insertion & Extraction User Manual Rev 1.0*
Mobile Pentium II Processor Mobile Module 400-Pin BGA Connector Assembly Development
Guide Rev. 1.0*
Focused Discussion on Intel Mobile Modules Design for Mfg. & Best Methods for MHPG
Customers Rev. 1.0 (OR-1385)
EMI Design Guide (ORMD6-0859)
Intel Mobile Module Newsletters*
Intel Mobile Module Thermal Diode Temperature Sensor Application Note*
Intel MMC-2 Standoff/Receptacle Height Spreadsheet*
AGP Interface Specification Revision 2.0*
*Available now, contact your Intel Field Representative
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Datasheet
1
Pentium III Processor Mobile Module MMC-2
2.0
Architecture Overview
A highly integrated assembly, the Pentium III processor mobile module contains the mobile
Pentium III processor core that runs at speeds of 450 MHz and 500 MHz with a 100-MHz processor
system bus speed (PSB).
The Intel 440BX AGPset provides immediate system-level support and includes the PIIX4E/M
PCI/ISA Bridge and the 82443BX Host Bridge. The PIIX4E/M provides extensive power
management capabilities and supports the Intel 82443BX Host Bridge. A notebook’s system
electronics must include a PIIX4E/M device to connect to the Pentium III processor mobile module.
Key features of the Intel 82443BX Host Bridge include: the DRAM controller supporting SDRAM
at 3.3Vwith a burst read at 4-1-1-1; a PCI CLKRUN# signal to request the PIIX4E/M to regulate
the PCI clock on the PCI bus; the 82443BX clock enables Self-Refresh mode of SDRAM during
Suspend mode and is compatible with SMRAM (C_SMRAM) and Extended SMRAM
(E_SMRAM) modes of power management; and E_SMRAM mode supports write-back cacheable
SMRAM up to 1 MB.
The thermal transfer plates (TTP) on the mobile Pentium III processor and the 82443BX Host
Bridge provide heat dissipation and thermal attach points for the manufacturer’s thermal solution.
An on-board voltage regulator converts the system DC voltage to the processor’s core and I/O
voltage. Isolating the processor voltage requirements allows the system manufacturer to
incorporate different processor variants into a single notebook system. Supporting input voltages
from 7.5V to 21.0V, the integrated module voltage regulator enables an above 80% peak efficiency
and de-couples the processor voltage requirements from the system.
Also incorporated is active thermal feedback (ATF) sensing, compliant with the ACPI Specification
Rev 1.0. Figure 1 illustrates the block diagram of the mobile module.
2
Datasheet
245304-004
Pentium III Processor Mobile Module MMC-2
Figure 1. Pentium III Processor Mobile Module Block Diagram
Mobile
Pentium III
Processor
Core
Processor Core Voltage
VTT
R
-
G
T
L
CPU
Voltage
Reg
ATF
Sense
82443BX
"Northbridge"
V_3
400-Pin, Board-to-Board Connector
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Datasheet
3
Pentium III Processor Mobile Module MMC-2
3.0
Signal Information
This section provides information on the signal groups for the Pentium III processor mobile
module. The signals are defined for compatibility with future Intel mobile modules.
3.1
Signal Definitions
Table 1 provides a list of signals by category and the corresponding number of signals in each
category. For proper signal termination, please contact your Intel Field Representative for more
information.
Table 1. Connector Signal Summary
Signal Group
Number of Pins
Memory
109
60
58
8
AGP
PCI
Processor/PIIX4E/M Sideband
Power Management
Clocks
7
9
Voltage: V_DC
Voltage: V_3S
Voltage: V_3
Voltage: V_5
Voltage: VCCAGP
Voltage: V_CPUPU
Voltage: V_CLK
ITP/JTAG
20
9
16
3
4
1
1
9
Module ID
4
Ground
45
37
400
Reserved
Total
4
Datasheet
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Pentium III Processor Mobile Module MMC-2
3.1.1
Signal List
The following notations are used to denote signal type:
I
Input pin
O
Output pin
O D
I D
I/O D
I/O
Open-drain output pin requiring a pullup resistor
Open-drain input pin requiring a pullup resistor
Input/Open-drain output pin requiring a pullup resistor
Bi-directional input/output pin
The signal description also includes the type of buffer used for a particular signal:
GTL+
PCI
Open-drain GTL+ interface signal
PCI bus interface signals
AGP
AGP bus interface signals
CMOS
The CMOS signals, depending on functional group, are 1.5V, 2.5V, or 3.3V.
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Datasheet
5
Pentium III Processor Mobile Module MMC-2
3.1.2
Memory Signal Description
Table 2 provides descriptions of the memory interface signals.
Table 2. Memory Signal Descriptions
Name
Type
Voltage
Description
Memory ECC Data: These signals carry Memory ECC data during
access to DRAM.
I/O
MECC[7:0]
V_3
CMOS
ECC is not supported on the mobile module.
O
Chip Select (SDRAM): These pins activate the SDRAMs. SDRAM
accepts any command when its CS# pin is active low.
CSA[5:O]#
DQMA[7:0]
V_3
V_3
CMOS
Input/Output Data Mask (SDRAM): These pins act as synchronized
output enables during a read cycle and as a byte mask during a write
cycle.
O
CMOS
Memory Address (SDRAM): This is the row and column address for
DRAM. The 82443BX Host Bridge system controller has two identical
sets of address lines (MAA and MAB#). The mobile module supports
only the MAB set of address lines. For additional addressing features,
please refer to the Intel 440BX AGPSet: 82443BX Host Bridge/
Controller Datasheet (Order Number: 290633-001).
MAB[9:0]#
MAB[10]
O
V_3
MAB[12:11]#
MAB[13]
CMOS
O
Memory Write Enable (SDRAM): MWEA# should be used as the
write enable for the memory data bus.
MWEA#
SRASA#
V_3
V_3
CMOS
SDRAM Row Address Strobe (SDRAM): When active low, this
signal latches Row Address on the positive edge of the clock. This
signal also allows Row access and pre-charge.
O
CMOS
SDRAM Column Address Strobe (SDRAM): When active low, this
signal latches Column Address on the positive edge of the clock. This
signal also allows Column access.
O
SCASA#
V_3
CMOS
SDRAM Clock Enable (SDRAM): SDRAM clock enable pin. When
these signals are deasserted, SDRAM enters power-down mode.
Each row is individually controlled by its own clock enable.
O
CKE[5:0]
MD[63:0]
V_3
V_3
CMOS
O
Memory Data: These signals are connected to the DRAM data bus.
They are not terminated on the mobile module.
CMOS
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Pentium III Processor Mobile Module MMC-2
3.1.3
AGP Signals
Table 3 provides descriptions of the AGP interface signals.
Table 3. AGP Signal Descriptions
Name
Type
Voltage
Description
AGP Address/Data: The standard AGP address and data lines. This
bus functions in the same way as the PCI AD[31:0] bus. The address
is driven with FRAME# assertion, and data is driven or received in
following clocks.
I/O
GAD[31:]
V_3
V_3
V_3
V_3
AGP
AGP Command/Byte Enable: This bus carries the command
information during AGP cycles when PIPE# is used. During an AGP
write, this bus contains byte enable information. The command is
driven with FRAME# assertion, and byte enables corresponding to
supplied or requested data are driven on the following clocks.
I/O
GC/BE[3:0]#
GFRAME#
GDEVSEL#
AGP
AGP Frame: GFRAME# is not used during AGP transactions. This
signal remains deasserted by an internal pullup resistor. Assertion
indicates the address phase of a PCI transfer. Negation indicates that
the cycle initiator desires one more data transfer.
I/O
AGP
AGP Device Select: This signal provides the same function as PCI
DEVSEL#, and it is not used during AGP transactions. The 82443BX
Host Bridge system controller drives this signal when a PCI initiator is
attempting to access DRAM. DEVSEL# is asserted at medium
decode time.
I/O
AGP
AGP Initiator Ready: GIRDY# indicates the AGP-compliant target is
ready to provide all write data for the current transaction. This signal
is asserted when the initiator is ready for a data transfer.
I/O
GIRDY#
GTRDY#
V_3
V_3
AGP
AGP Target Ready: This signal indicates the AGP-compliant master
is ready to provide all write data for the current transaction. GTRDY#
is asserted when the target is ready for a data transfer.
I/O
AGP
AGP Stop: This signal provides the same function as PCI STOP#,
and it is not used during AGP transactions. GSTOP# is asserted by
the target to request the master to stop the current transaction.
I/O
GSTOP#
GREQ#
V_3
V_3
AGP
I
AGP Request: AGP master requests for AGP.
AGP
AGP Grant: GGNT# provides the same function as on PCI.
Additional information is provided on the ST[2:0] bus.
O
GGNT#
GPAR
V_3
V_3
AGP
PCI Grant: Permission is given to the master to use PCI.
I/O
AGP Parity: A single parity bit is provided over GAD[31:0] and GC/
BE[3:0]. This signal is not used during AGP transactions.
AGP
Pipelined Request: PIPE# is asserted by the current master to
indicate that a full-width address is to be queued by the target. The
master queues one request each rising clock edge while PIPE# is
asserted.
I
PIPE#
AGP
V_3
I
Sideband Address: This bus provides an additional conduit to pass
address and commands to the 82443BX Host Bridge System
Controller from the AGP master.
SBA[7:0]
RBF#
AGP
V_3
V_3
I
Read Buffer Full: Indicates if the master is ready to accept
previously requested, low-priority read data.
AGP
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Pentium III Processor Mobile Module MMC-2
Table 3. AGP Signal Descriptions
Name
Type
Voltage
Description
Status Bus: This bus provides information from the arbiter to an AGP
Master on what it may do. These bits only have meaning when GGNT
is asserted.
O
ST[2:0]
V_3
AGP
AD Bus Strobes: These signals provide timing for double-clocked
data on the GAD bus. The agent providing data drives these signals,
and the signals are identical copies of each other.
I/O
ADSTB[B:A]
SBSTB
V_3
V_3
AGP
I/O
Sideband Strobe: This signal provides timing for a sideband bus.
The SBA[7:0] (AGP master) drives the sideband strobe.
AGP
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3.1.4
PCI Signals
Table 4 provides descriptions of the PCI signals.
Table 4. PCI Signal Descriptions
Name
Type
Voltage
Description
Address/Data: The standard PCI address and data lines. The
address is driven with FRAME# assertion, and data is driven or
received in the following clocks.
I/O
AD[31:0]
C/BE[3:0]
FRAME#
DEVSEL#
V_3
V_3
V_3
V_3
PCI
Command/Byte Enable: The command is driven with FRAME#
assertion, and byte enables corresponding to supplied or requested
data are driven on the following clocks.
I/O
PCI
Frame: Assertion indicates the address phase of a PCI transfer.
Negation indicates that the cycle initiator desires one more data
transfer.
I/O
PCI
Device Select: The 82443BX Host Bridge drives this signal when a
PCI initiator is attempting to access DRAM. DEVSEL# is asserted at
medium decode time.
I/O
PCI
I/O
IRDY#
TRDY#
STOP#
V_3
V_3
V_3
Initiator Ready: Asserted when the initiator is ready for data transfer.
Target Ready: Asserted when the target is ready for a data transfer.
PCI
I/O
PCI
I/O
Stop: Asserted by the target to request the master to stop the current
transaction.
PCI
Lock: Indicates an exclusive bus operation and may require multiple
transactions to complete. When LOCK# is asserted, non-exclusive
transactions may proceed. The 82443BX supports lock for CPU
initiated cycles only. PCI initiated locked cycles are not supported.
I/O
PLOCK#
V_3
PCI
I
REQ[4:0]#
GNT[4:0]#
V_3
V_3
PCI Request: PCI master requests for PCI.
PCI
O
PCI Grant: Permission is given to the master to use PCI.
PCI
PCI Hold: This signal comes from the expansion bridge. It is the
bridge request for PCI. The 82443BX Host Bridge will drain the DRAM
write buffers, drain the processor-to-PCI posting buffers, and acquire
the host bus before granting the request via PHLDA#. These
processes ensure that GAT timing is met for ISA masters. The
PHOLD# protocol has been modified to include support for passive
release.
I
PHOLD#
V_3
PCI
PCI Hold Acknowledge: The 82443BX Host Bridge drives this signal
to grant PCI to the expansion bridge. The PHLDA# protocol has been
modified to include support for passive release.
O
PHLDA#
PAR
V_3
V_3
PCI
I/O
Parity: A single parity bit is provided over AD[31:0] and C/BE[3:0]#.
PCI
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Pentium III Processor Mobile Module MMC-2
Table 4. PCI Signal Descriptions
Name
Type
Voltage
Description
System Error: The 82443BX asserts this signal to indicate an error
condition. For further information, refer to the Intel 440BX AGPSet:
82443BX Host Bridge/Controller Datasheet (Order Number: 290633-
001).
I/O
SERR#
V_3
PCI
Clock Run: An open-drain output and input. The 82443BX Host
Bridge requests the central resource, PIIX4E/M, to start or maintain
the PCI clock by asserting CLKRUN#. The 82443BX Host Bridge tri-
states CLKRUN# upon deassertion of Reset (since CLK is running
upon deassertion of Reset).
I/O D
PCI
CLKRUN#
PCI_RST#
V_3
V_3
Reset: When asserted, this signal asynchronously resets the
82443BX Host Bridge. The PCI signals also tri-state, compliant with
PCI Revision 2.1 Specifications.
I
CMOS
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Pentium III Processor Mobile Module MMC-2
3.1.5
Processor and PIIX4E/M Sideband Signals
Table 5 provides descriptions of the processor and PIIX4E/M sideband signals.
Table 5. Processor and PIIX4E/M Sideband Signal Descriptions
Name
Type
Voltage
Description
Numeric Co-processor Error: This signal functions as an FERR#
signal supporting co-processor errors. This signal is tied to the co-
processor error signal on the processor and is pulled active low by the
processor to the PIIX4E/M.
O D
FERR#
V_CPUPU
CMOS
I D
Ignore Error: This open-drain signal is connected to the Ignore Error
pin on the processor and is driven by the PIIX4E/M.
IGNNE#
INT#
V_CPUPU
V_CPUPU
CMOS
I D
Initialization: INIT# is asserted by the PIIX4E/M to the processor for
system initialization. This signal is an open-drain.
CMOS
Processor Interrupt: The PIIX4E/M drives INTR to signal the
processor that an interrupt request is pending and needs to be serviced.
This signal is an open-drain.
I D
INTR
NMI
V_CPUPU
V_CPUPU
V_CPUPU
V_CPUPU
CMOS
Non-maskable Interrupt: NMI is used to force a non-maskable
interrupt to the processor. The PIIX4E/M ISA bridge generates an NMI
when either SERR# or IOCHK# is asserted, depending on how the NMI
Status and Control Register is programmed. This signal is an open-
drain.
I D
CMOS
Address Bit 20 Mask: When enabled, this open-drain signal causes
the processor to emulate the address wraparound at 1 MB, which
occurs on the Intel 8086 processor.
I D
A20M#
SMI#
CMOS
System Management Interrupt: SMI# is an active-low synchronous
output from the PIIX4E/M that is asserted in response to one of many
enabled hardware or software events. The SMI# open-drain signal can
be an asynchronous input to the processor. However, in this chipset
SMI# is synchronous to PCLK.
I D
CMOS
Stop Clock: STPCLK# is an active-low, synchronous open-drain output
from the PIIX4E/M that is asserted in response to one of many
hardware or software events. STPCLK# connects directly to the
processor and is synchronous to PCICLK. When the processor samples
STPCLK# asserted, it responds by entering a low-power state (Quick
Start). The processor will only exit this mode when this signal is
deasserted.
I D
STPCLK#
V_CPUPU
CMOS
NOTE: See Table 8 for V_CPUPU definition.
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3.1.6
Power Management Signals
Table 6 provides descriptions of the power management signals. The SM_CLK and SM_DATA
signals refer to the two-wire serial SMBus interface. Although this interface is currently used
solely for the digital thermal sensor, the SMBus contains reserved serial addresses for future use.
Table 6. Power Management Signal Descriptions
Name
Type
Voltage
Description
Suspend Status: This signal connects to the SUS_STAT1#
output of PIIX4E/M. It provides information on host clock status
and is asserted during all suspend states.
I
SUS_STAT1#
V_3ALWAYS
CMOS
VR_ON: Voltage regulator ON. This 3.3-V (5.0-V tolerant) signal
controls the operation of the voltage regulator. VR_ON should
be generated as a function of the PIIX4E/M SUSB# signal,
which is used for controlling the “Suspend State B” voltage
planes. This signal should be driven by a digital signal with a
I
VR_ON
V_3
CMOS
rise/fall time of less than or equal to 1 µS. (V
= 0.4V, V
IL (max)
IH
= 3.0V.)
(min)
VR_PWRGD: The mobile module drives this signal high to
indicate that the voltage regulator is stable. The signal is pulled
low using a 100-K resistor when inactive, and it can be used in
some combination to generate the system PWRGOOD signal.
VR_PWRGD
BXPWROK
O
V_3
V_3
Power OK to BX: This signal must go active at least 1 mS after
the V_3 power rail is stable and 1 mS prior to deassertion of
PCIRST#.
I
CMOS
I/O D
Serial Clock: This clock signal is used on the SMBus interface
to the digital thermal sensor.
SM_CLK
SM_DATA
ATF_INT#
V_3
V_3
V_3
CMOS
I/O D
Serial Data: Open-drain data signal on the SMBus interface to
the digital thermal sensor.
CMOS
O D
ATF Interrupt: This signal is an open-drain output signal of the
digital thermal sensor.
CMOS
NOTE: V_3ALWAYS is a 3.3-V supply. It is generated whenever V_DC is available and supplied to PIIX4E/M
resume well.
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3.1.7
Clock Signals
Table 7 provides descriptions of the clock signals.
Table 7. Clock Signal Descriptions
Name
Type
Voltage
Description
PCI Clock In: PCLK, an input to the mobile module, is one of the
system’s PCI clocks. All of the 82443BX Host Bridge logic uses this
clock in the PCI clock domain. This clock is stopped when the PIIX4E/
M PCI_STP# signal is asserted and/or during all suspend states.
I
PCLK
V_3
PCI
Host Clock In: This clock is an input to the mobile module from the
CK100-M/CK100-SM clock source. The processor and the 82443BX
Host Bridge system controller use HCLK0. This clock is stopped when
the PIIX4E/M CPU_STP# signal is asserted and/or during all suspend
states.
I
HCLK0
V_CLK
CMOS
Note: HCLK0 and BCLK are used interchangeably.
Host Clock In: This clock is an input to the mobile module from the
CK100-M/CK100-SM clock source.
I
HCLK1
DCLK0
V_CLK
V_3
CMOS
This signal is not implemented on the mobile module.
SDRAM Clock Out: A 66-MHz SDRAM clock reference generated
internally by the 82443BX Host Bridge system controller onboard PLL.
It feeds an external buffer that produces multiple copies for the SO-
DIMMs.
O
CMOS
SDRAM Read Clock: Feedback reference from the SDRAM clock
buffer. The 82443BX Host Bridge System Controller uses this clock
when reading data from the SDRAM array.
I
DCLKRD
V_3
CMOS
This signal is not implemented on the mobile module.
SDRAM Write Clock: Feedback reference from the SDRAM clock
buffer. The 82443BX Host Bridge system controller uses this clock
when writing data to the SDRAM array.
I
DCLKWR
GCLKIN
V_3
V_3
CMOS
I
AGP Clock In: The GCLKIN input is a feedback reference from the
GCLKO signal.
CMOS
AGP Clock Out: This signal is generated by the 82443BX Host
Bridge system controller onboard PLL from the HCLK0 host clock
reference. The frequency of GCLKO is 66 MHz. The GCLKO output is
used to feed both the PLL reference input pins on the 82443BX Host
Bridge system controller and the AGP device. The board layout must
maintain complete symmetry on loading and trace geometry to
minimize AGP clock skew.
O
GCLKO
FQS
V_3
CMOS
O
Frequency Select: This output indicates the desired host clock
frequency for the mobile module.
V_3S
CMOS
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3.1.8
Voltage Signals
Table 8 provides descriptions of the voltage signals.
Table 8. Voltage Descriptions
Number
of pins
Name
Type
Description
V_DC
V_3S
I
20
9
DC Input: 7.5V ~ 21.0V
SUSB# Controlled 3.3V: Power managed 3.3-V supply. An output
of the voltage regulator on the system electronics. This rail is off
during STR, STD, and Soff.
I
I
I
SUSC# Controlled 5.0V: Power managed 5.0-V supply. An output
of the voltage regulator on the system electronics. This rail is off
during STD and Soff.
V_5
V_3
3
SUSC# Controlled 3.3V: Power managed 3.3-V supply. An output
of the voltage regulator on the system electronics. This rail is off
during STD and Soff.
16
AGP I/O Voltage: This voltage rail is not implemented on the
mobile module and is defined for upgrade purposes only. Intel
recommends that this voltage rail be connected to V_3 on the
system electronics.
VCCAGP
I
4
Processor I/O Ring: The mobile module drives V_CPUPU to
power processor interface signals, such as the PIIX4E/M open-
drain pullups for the processor and PIIX4E/M sideband signals.
V_CPUPU is tied to 1.5V.
V_CPUPU
V_CLK
O
O
1
1
Processor Clock Rail: The mobile module drives V_CLK to power
CK100-M VDDCPU rail.
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3.1.9
ITP and JTAG Pins
Table 9 provides descriptions of the ITP and JTAG signals, which the system manufacturer can use
to implement a JTAG chain and an ITP port if desired.
Table 9. ITP and JTAG Pins
Name
Type
Voltage
Description
JTAG Test Data Out: A serial output port. TAP instructions and data
are shifted out of the processor from this port.
TDO
TDI
O
V_CPUPU
JTAG Test Data In: A serial input port. TAP instructions and data are
shifted into the processor from this port.
I
I
I
I
I
VTT
VTT
VTT
VTT
VTT
JTAG Test Mode Select: Controls the TAP controller change
sequence.
TMS
JTAG Test Clock: Testability clock for clocking the JTAG boundary
scan sequence.
TCLK
JTAG Test Reset: Asynchronously resets the TAP controller in the
processor.
TRST#
Debug Mode Request: Driven by the ITP – makes request to enter
debug mode.
FS_PREQ#
Debug Mode Ready: Driven by the processor – informs the ITP that
the processor is in debug mode.
FS_PRDY#
O
O
VTT
VTT
FS_RESET#
Processor Reset: Processor reset status to the ITP.
GTL+ Termination Voltage: The POWERON pin uses VTT on the
ITP debug port to determine when target system is on. The
POWERON pin is pulled up using a 1-KΩ resistor to VTT. Other ITP
signals might use this power rail for pullup.
VTT
O
VTT
NOTE: FS_RESET# and FS_PRDY# are pulled up to VTT inside the mobile Pentium III processor core.
3.1.10
Miscellaneous Pins
Table 10 provides descriptions of the miscellaneous signal pins.
Table 10. Miscellaneous Pin Descriptions
Name
Type
Number
Description
Module Revision ID: These pins track the revision level of the mobile
module. A 100-K pullup resistor to V_3S must be placed on the system
electronics for these signals. See Section 8.0 for more detail.
O
Module ID[3:0]
Ground
4
CMOS
I
45
33
Ground
Unallocated Reserved pins.
Reserved
RSVD
All Reserved pins must not be connected.
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3.2
Connector Pin Assignments
Table 11 lists the signals for each pin of the connector to the system electronics. Refer to Section
3.3 for the pin assignments.
Table 11. Connector Pin Assignment
Pin
Number
Row A
Row B
Row C
Row D
Row E
1
SBA5
GAD25
ADSTBB
GAD24
GAD29
VCCAGP
GAD1
GND
SBA6
GAD31
SBA4
SBA7
SBA0
2
3
GAD30
GAD26
GAD4
GAD3
GAD2
V_3
GAD27
GAD6
GND
4
GND
GDA8
5
RBF#
GAD5
GC/BE0#
GND
6
BXPWROK
MD0
RESERVED
MD1
ADSTBA
CLKRUN#
MD32
7
GAD7
8
MD2
MD33
GND
MD34
9
MD36
MD4
MD3
MD35
MD34
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
MD7
MD38
MD37
MD40
GND
MD6
MD5
MD41
MD42
MD39
MD8
MD43
MD11
MD10
MD9
MD14
MD45
MD44
ND15
MD13
MD12
MECC4
SCASA#
GND
MECC0
MWEA#
MID1
ND47
ND46
MECC5
DQMA0
MID0
RESERVED
DQMA1
DQMA5
CSA3#
GND
RESERVED
CSA#
V_3
DQMA4
CSA2#
CSA5#
RESERVED
MAB4#
RESERVED
RESERVED
MAB11#
V_3
CSA1#
CSA4#
MAB0#
MAB2#
GND
GND
SRASA#
RESERVED
RESERVED
RESERVED
MAB8#
MAB1#
RESERVED
RESERVED
RESERVED
MSB9#
RESERVED
CKE0
RESERVED
MAB3#
MAB6#
MAB7#
MAB10
DCLK0
DCLKRD
GND
MAB5#
RESERVED
MAB12#
GND
RESERVED
MAB13
CKE1
MID2
CKE3
CE4
CKE5
CKE2
MID3
RESERVED
DCLKWR
FS_PREQ#
GND
RESERVED#
GND
RESERVED
GND
RESERVED
VTT
DQMA2
RESERVED
MD26
MD58
TDO
DQMA3
MD25
FS_RESET#
FS_PRDY#
RESERVED
RESERVED
V_3
GND
MD57
MD60
SMCLK
SMDAT
TCLK
FERR#
IGNNE#
TDI
TMS
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Table 11. Connector Pin Assignment
Pin
Row A
Number
Row B
Row C
Row D
Row E
34
35
36
37
38
39
40
RESERVED
RESERVED
V_CPUPU
V_CLK
FQS
V_5
RESERVED
V_3S
TRST#
V_3S
ATF_INT#
V_3S
V_5
V_3S
V_3S
V_3S
V_5
V_3S
V_3S
V_3S
RESERVED
V_DC
RESERVED
V_DC
V_DC
RESERVED
V_DC
RESERVED
V_DC
RESERVED
V_DC
V_DC
V_DC
V_DC
V_DC
Pin
Number
Row F
Row G
Row H
Row J
Row K
1
GREQ#
ST0
GND
ST1
PIP#
SBA1
SBA3
SBSTB
GND
GND
GCLKI
CGLK0
GAD23
GC/BE3#
GAD22
GAD21
GAD19
GAD28
AD1
2
3
GGNT#
GAD13
GAD12
GAD10
GAD11
GAD9
ST2
SBA2
4
GSTOP#
GPAR
GAD15
GC/BE1#
GAD14
VCCAGP
AD4
GAD16
GAD18
GFRAME#
GTRDY#
GDEVESEL#
GND
GAD20
GAD17
GND
5
6
7
GC/BE2#
GIRDY#
VCCAGP
AD3
8
9
GND
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
AD0
AD2
GND
C/BE0#
AD10
AD6
GND
AD5
VCCAGP
MECC1
SERR#
AD16
AD7
AD8
AD9
AD13
GND
AD12
AD11
PAR
AD15
C/BE1#
DEVSEL#
GND
AD14
TRDY#
GND
STOP#
AD17
PLOCK#
AD18
AD19
AD23
AD30
AD24
C/BE2#
AD26
AD21
AD27
AD22
C/BE3#
AD20
PCLK
GND
PCI_RST#
RESERVED
IRDY#
GND
GND
AD28
PHOLD#
FRAME#
GNT2#
GNT4#
PHLDA#
MECC7
MD48
AD31
AD29
AD25
GND
REQ1#
REQ3#
REQ4#
V_3
REQ0#
GNT3#
GND
REQ2#
GNT0#
GND
GNT1#
GND
MD59
MD54
MD24
DQMA6
MECC2
MD50
MD18
MD51
MD52
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Pentium III Processor Mobile Module MMC-2
27
28
29
30
31
32
33
34
35
36
37
38
39
40
DQMA7
MECC6
MECC3
MD27
GND
MD16
MD17
MD19
MD21
GND
MD53
MD22
MD62
MD30
GND
MD23
MD55
MD56
MD63
MD31
GND
MD49
MD20
MD28
GND
MD29
MD61
DMI#
INTR
VR_ON
VR_PWRGD
INIT#
NMI
SUS_STAT1#
STPCLK#
V_3
GND
HCLK0
GND
A20M#
V_3
GND
V_3
GND
HCLK1
GND
V_3
V_3
V_3
GND
V_3
V_3
V_3
V_3
V_3
RESERVED
V_DC
V_DC
RESERVED
V_DC
RESERVED
V_DC
RESERVED
V_DC
V_DC
RESERVED
V_DC
V_DC
V_DC
V_DC
3.3
Pin and Pad Assignments
The 400-pin MMC-2 connector has a 1.27-mm pitch and a BGA style surface mount. Refer to
Section 6.1.3 for size information. Figure 2 shows the MMC-2 connector pad assignments.
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Pentium III Processor Mobile Module MMC-2
Figure 2. MMC-2 Connector Pad Footprint
400-Pin Connector Footprint
OEM Pad Assignments
K
A
1
40
Table 12 summarizes some of the connector key specifications.
Table 12. Connector Specifications
Parameter
Condition
Specification
Contact
Housing
Current
Voltage
Copper Alloy
Material
Thermo-Plastic Molded Compound: LCP
0.5A
50 VAC
Electrical
Insulation Resistance
Termination Resistance
Capacitance
100 MΩ
20-mΩ maximum at 20-mV open circuit with 10 mA
5-pF maximum per contact
50 Cycles
Mating Cycles
Mechanical
Connector Mating Force
Contact Unmating Force
50 lbs (22.7 kg) maximum
30 lbs (13.6 kg) maximum
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Pentium III Processor Mobile Module MMC-2
4.0
Functional Description
4.1
Pentium III Processor Mobile Module MMC-2
The mobile Pentium III processor core runs at speeds of 450 MHz and 500 MHz with a 100-MHz
PSB.
4.2
4.3
L2 Cache
The on-die L2 cache has 256 KB, is eight-way set associative, and runs at the speed of the
processor core.
The 82443BX Host Bridge System Controller
Intel’s 82443BX Host Bridge system controller is a highly integrated device that combines the bus
controller, the DRAM controller, and the PCI bus controller into one component. The 82443BX
Host Bridge has multiple power management features designed specifically for notebook systems
such as:
• CLKRUN#, a feature that enables controlling of the PCI clock on or off.
• The 82443BX Host Bridge suspend modes, which include Suspend-To-RAM (STR), Suspend-
To-Disk (STD), and Power-On-Suspend (POS).
• System Management RAM (SMRAM) power management modes, which include Compatible
SMRAM (C_SMRAM) and Extended SMRAM (E_SMRAM). C_SMRAM is the traditional
SMRAM feature implemented in all Intel PCI chipsets. E_SMRAM is a new feature that
supports write-back cacheable SMRAM space up to 1 MB. To minimize power consumption
while the system is idle, the internal 82443BX Host Bridge clock is turned off (gated off) when
there is no processor and PCI activity. This is accomplished by setting the G_CLK enable bit
in the power management register in the 82443BX through the system BIOS.
4.3.1
Memory Organization
The memory interface of the 82443BX Host Bridge is available at connector. This allows for the
following:
• One set of memory control signals, sufficient to support up to three SO-DIMM sockets and six
banks of SDRAM at 100 MHz.
• One CKE signal for each bank.
Memory features not supported by the 82443BX Host Bridge system controller standard MMC-2
mode are:
• Eight banks of memory
• 256-Mb memory devices
• Second set of memory address lines (MAA[13:0])
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• Extended Data Out (EDO) DRAM
• 66-MHz memory bus
The clocking architecture supports the use of SDRAM. The clocking mode for 100-MHz SDRAM
memory configurations allows all host and SDRAM clocks to be generated from the same clocking
source on the system electronics. For complete details about memory device support, organization,
size, and addressing when using SDRAM memory and trace length guidelines, refer to the Intel®
Pentium® III Processor Mobile Module System Electronics 100-MHz Layout Guidelines Revision.
1.0 (OR-1780).
4.3.2
Reset Strap Options
Several strap options on the memory address bus define the behavior of the Pentium III processor
mobile module after reset. Other straps are allowed to override the default settings. Table 13 shows
the various straps and their implementation.
Table 13. Configuration Straps for the 82443BX Host Bridge System Controller
Optional Override on
System Electronics
Signal
Function
Module Default Setting
Strapped high on the module for 100
MHz
MAB[12]#
MAB[11]#
MAB[10]#
Host Frequency Select
In Order Queue Depth
Quick Start Select
None
No strap, maximum queue depth is set
at 8
None
None
Strapped high on the module for Quick
Start mode
MAB[9]#
MAB[7]#
AGP Disable
No strap (AGP is enabled)
Strap high to disable AGP
None
MM Configuration
No strap (standard MMC-2 mode)
Host Bus Buffer Mode
Select
Strapped high on the module for
mobile PSB buffers
MAB[6]#
None
4.3.3
PCI Interface
The PCI interface of the 82443BX Host Bridge is available at the MMC-2 connector. The
82443BX Host Bridge supports the PCI Clockrun protocol for PCI bus power management. In this
protocol, PCI devices assert the CLKRUN# open-drain signal when they require the use of the PCI
interface. Refer to the PCI Mobile Design Guide for complete details on the PCI Clockrun
protocol.
The 82443BX Host Bridge is responsible for arbitrating the PCI bus. The 82443BX Host Bridge
can support up to five PCI bus masters. There are five PCI Request/Grant pairs (REQ[4:0]# and
GNT[4:0]#) available on the connector to the system electronics.
Note: The PCI interface on the MMC-2 connector is 3.3V only. PCI devices that are 5.0V are not
supported.
The 82443BX Host Bridge system controller is compliant with the PCI 2.1 Specification, which
improves the worst case PCI bus access latency from earlier PCI specifications. The 82443BX
Host Bridge supports only Mechanism #1 for accessing PCI configuration space. This implies that
signals AD[31:11] are available for PCI IDSEL signals. However, since the 82443BX Host Bridge
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Pentium III Processor Mobile Module MMC-2
is always device #0, AD11 will never be asserted during PCI configuration cycles as an IDSEL.
The 82443BX reserves AD12 for the AGPbus. Thus, AD13 is the first available address line usable
as an IDSEL. Intel recommends that AD18 be used by the PIIX4E/M.
4.3.4
AGP Interface
The 82443BX Host Bridge system controller is compliant with the AGP Interface Specification
Revision 2.0, which supports an asynchronous AGP interface coupling to the 82443BX core
frequency. The AGP interface can achieve real data throughput in excess of 500 MB per second
using an AGP 2X graphics device. Actual bandwidth may vary depending on specific hardware
and software implementations.
4.4
Power Management
4.4.1
Clock Control Architecture
The clock control architecture has been optimized for notebook designs. The clock control
architecture consists of seven different clock states: Normal, Stop Grant, Auto Halt, Quick Start,
HALT/Grant Snoop, Sleep, and Deep Sleep states. The Auto Halt state provides a low-power clock
state that can be controlled through the software execution of the HLT instruction. The Quick Start
state provides a very low-power, low-exit latency clock state that can be used for hardware
controlled "idle" states. The Deep Sleep state provides an extremely low-power state that can be
used for Power-On-Suspend states, which is an alternative to shutting off the processor’s power.
The exit latency of the Deep Sleep state is 30 µS in the mobile module. The Stop Grant state and
the Quick Start clock state are mutually exclusive. For example, a strapping option on signal A15#
chooses which state is entered when the STPCLK# signal is asserted. Strapping the A15# signal to
ground at Reset enables the Quick Start state. Otherwise, asserting the STPCLK# signal puts the
processor into the Stop Grant state.
Table 14 provides information on the clock control states and Figure 3 illustrates the clock control
architecture. Performing state transitions not shown in Figure 3 are neither recommended nor
supported.
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Table 14. Clock State Characteristics
Clock State
Exit Latency
Snooping
System Uses
Notes
Note 4
Normal
N/A
Yes
Normal program execution
Software controlled entry idle
mode
Auto Halt
Approximately 10 bus clocks
Yes
Yes
Note 2
Note 1
Hardware controlled entry/exit
mobile throttling
Stop Grant
10 bus clocks
Through Snoop, to HALT/Grant
Snoop state: immediate
Hardware controlled entry/exit
mobile throttling
Quick Start
Yes
Note 2
Through STPCLK#, to Normal state:
10 bus clocks
HALT/Grant A few bus clocks after the end of
Supports snooping in the low-
power states
Yes
No
No
Snoop
snoop activity
Hardware controlled entry/exit
desktop idle mode support
Sleep
To Stop Grant state 10 bus clocks
Note 1
Note 3
Hardware controlled entry/exit
mobile POS support
Deep Sleep 30 µS
NOTES:
1. Intel mobile modules do not support the Sleep and Stop Grant clock states.
2. These values are not 100% tested and are specified at 50°C by design and characterization.
3. This value is not 100% tested and is specified at 35°C by design and characterization.
4. Specification labeled N/A are not available.
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Figure 3. Clock Control States
STPCLK# and
QSE and SGA
Normal
Quick
Start
State
HS=false
(!STPCLK# and !HS)
or RESET#
STPCLK# and
QSE and SGA
HLT and
halt bus cycle
BCLK
stopped
halt
break
!STPCLK#
and HS
BCLK on
and QSE
STPCLK# and
!QSE and SGA
Auto
Snoop
serviced
Snoop
occurs
Deep
Sleep
Halt
HS=true
(!STPCLK#
and !HS) or
stop break
!STPCLK#
and HS
Snoop
occurs
STPCLK# and
!QSE and SGA
Snoop
serviced
Snoop
occurs
Stop
Grant
HALT/Grant
Snoop
Snoop
serviced
BCLK on
and !QSE
SLP#
BCLK
stopped
!SLP# or
RESET#
Sleep
NOTES: Halt break – A20M#, BINIT#, FLUSH#, INIT#, INTR, NMI, PREQ#, RESET#, SMI#
HLT – HLT instruction executed
HS – Processor Halt State
QSE – Quick Start State Enabled
SGA – Stop Grant Acknowledge bus cycle issued
Stop break – BINIT#, FLUSH#, RESET#
Intel mobile modules do not support shaded clock control states
4.4.1.1
4.4.1.2
Normal State
The Normal states is the normal operating mode where the processor’s core clock is running, and
the processor is actively executing instructions.
Auto Halt State
This is a low-power mode entered by the processor through the execution of the HLT instruction.
The power level of this mode is similar to the Stop Grant state. A transition to the Normal state is
made by a halt break event (one of the following signals going active: NMI, INTR, BINIT#, INIT#,
RESET#, FLUSH#, or SMI#).
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Asserting the STPCLK# signal while in the Auto Halt state will cause the processor to transition to
the Stop Grant state or the Quick Start state, where a Stop Grant Acknowledge bus cycle will be
issued. Deasserting STPCLK# will cause the processor to return to the Auto Halt state without
issuing a new Halt bus cycle.
The SMI# (System Management Interrupt) is recognized in the Auto Halt state. The return from the
SMI handler can be to either the Normal state or the Auto Halt state. See the Intel® Architecture
Software Developer's Manual, Volume III: System Programmer's Guide for more information. No
Halt bus cycle is issued when returning to the Auto Halt state from System Management Mode
(SMM).
The FLUSH# signal is serviced in the Auto Halt state. After flushing the on-chip, the processor
will return to the Auto Halt state without issuing a Halt bus cycle. Transitions in the A20M# and
PREQ# signals are recognized while in the Auto Halt state.
4.4.1.3
Stop Grant State
Intel mobile modules do not support the Stop Grant state.
In desktop systems, the processor enters this mode with the assertion of the STPCLK# signal when
it is configured for Stop Grant state (via the A15# strapping option). The processor is still able to
respond to snoop requests and latch interrupts. Latched interrupts will be serviced when the
processor returns to the Normal state. Only one occurrence of each interrupt event will be latched.
A transition back to the Normal state can be made by the deassertion of the STPCLK# signal, or the
occurrence of a stop break event (a BINIT#, FLUSH#, or RESET# assertion).
The processor will return to the Stop Grant state after the completion of a BINIT# bus initialization
unless STPCLK# has been deasserted. RESET# assertion will cause the processor to immediately
initialize itself. However, the processor will stay in the Stop Grant state after initialization until
STPCLK# is deasserted. If the FLUSH# signal is asserted, the processor will flush the on-chip
caches and return to the Stop Grant state. A transition to the Sleep state can be made by the
assertion of the SLP# signal.
While in the Stop Grant state, assertions of SMI#, INIT#, INTR, and NMI (or LINT[1:0]) will be
latched by the processor. These latched events will not be serviced until the processor returns to the
Normal state. Only one of each event will be recognized upon return to the Normal state.
4.4.1.4
Quick Start State
This is a mode entered by the processor with the assertion of the STPCLK# signal when it is
configured for the Quick Start state (via the A15# strapping option). In the Quick Start state the
processor is only capable of acting on snoop transactions generated by the PSB priority device.
Because of its snooping behavior, Quick Start can only be used in single processor configurations.
A transition to the Deep Sleep state can be made by stopping the clock input to the processor. A
transition back to the Normal state (from the Quick Start state) is made only if the STPCLK# signal
is deasserted.
While in this state the processor is limited in its ability to respond to input. It is incapable of
latching any interrupts, servicing snoop transactions from symmetric bus masters, or responding to
FLUSH# and BINIT# assertions. In the Quick Start state, the processor will not respond properly to
any input signal other than STPCLK#, RESET#, or BPRI#. If any other input signal changes, then
the behavior of the processor will be unpredictable. No serial interrupt messages may begin or be in
progress while the processor is in the Quick Start state.
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RESET# assertion will cause the processor to immediately initialize itself, but the processor will
stay in the Quick Start state after initialization until STPCLK# is deasserted.
4.4.1.5
HALT/Grant Snoop State
The processor will respond to snoop transactions on the PSB while in the Auto Halt, Stop Grant, or
Quick Start state. When a snoop transaction is presented on the system bus, the processor will enter
the HALT/Grant Snoop state. The processor will remain in this state until the snoop has been
serviced and the PSB is quiet. After the snoop has been serviced, the processor will return to its
previous state. If the HALT/Grant Snoop state is entered from the Quick Start state, then the input
signal restrictions of the Quick Start state still apply in the HALT/Grant Snoop state (except for
those signal transitions that are required to perform the snoop).
4.4.1.6
Sleep State
Intel mobile modules do not support the Sleep state.
In desktop systems, the Sleep state is a very low-power state in which the processor maintains its
context and the phase locked loop (PLL) maintains phase lock. The Sleep state can only be entered
from the Stop Grant state. After entering the Stop Grant state the SLP# signal can be asserted,
causing the processor to enter the Sleep state. The SLP# signal is not recognized in the Normal
state or the Auto Halt state.
The processor can be reset by the RESET# signal while in the Sleep state. If RESET# is driven
active while the processor is in the Sleep state, then SLP# and STPCLK# must immediately be
driven inactive to ensure that the processor correctly initializes itself.
Input signals (other than RESET#) may not change while the processor is in or transitioning into or
out of the Sleep state. Input signal changes at these times will cause unpredictable behavior. Thus,
the processor is incapable of snooping or latching any events in the Sleep state.
While in the Sleep state the processor can enter its lowest power state, the Deep Sleep state.
Removing the processor’s input clock puts the processor in the Deep Sleep state. PICCLK may be
removed in the Sleep state.
4.4.1.7
Deep Sleep State
The Deep Sleep state is the lowest power mode the processor can enter while maintaining its
context. Stopping the BCLK input to the processor enters the Deep Sleep state, while it is in the
Sleep state or the Quick Start state. For proper operation, the BCLK input should be stopped in the
low state.
The processor will return to the Sleep state or the Quick Start state from the Deep Sleep state when
the BCLK input is restarted. Due to the PLL lock latency, there is a 30-µS delay after the clocks
have started before this state transition happens. PICCLK may be removed in the Deep Sleep state.
PICCLK should be designed to turn on when BCLK turns on when transitioning out of the Deep
Sleep state.
The input signal restrictions for the Deep Sleep state are the same as for the Sleep state, except that
RESET# assertion will result in unpredictable behavior.
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4.5
Power Consumption in Power Management Mode
The power data is broken down into each power rail. Each power rail is supplied to the module
through the MMC-2 connector. The total power values are based on typical power consumption.
The data is captured at Tamb = 25°C, T TTP = 25 °C, and V_DC = 18.0V.
Note: All power comumption values are not 100% tested and have been characterized by design.
Table 15 and Table 16 provide the module power consumption values in various power
management modes. Because mobile modules with the same frequencies may have different
printed circuit board (PCB) revisions, refer to the product tracking code (PTC) lists before each
table below to match the correct power consumption information with the correct mobile module.
Table 15 applies to mobile modules with the following PTCs.
• PML50002001AB
• PML45002001AB
• PML50002201AC
• PML45002201AC
Table 15. Power Consumption Values I
State
Auto Halt
V_DC
V_5
V_3
V_3S
Total Power
2.19W
1.77W
1.29W
0.04W
0.08W
0.08W
0.08W
0.01W
2.27W
2.04W
0.24W
0.01W
0.57W
0.62W
0.45W
0.00W
4.17W
3.43W
1.35W
0.05W
Quick Start
Deep Sleep
STR
NOTE: These power values should be used as power supply guidelines for power management modes. They
have some guardband added for design margin. Therefore, the total power does not necessarily add up
as the sum of each power rail. "Total Power" is the sum of the individual "raw" power requirements with
guardband added.
Table 16 applies to mobile modules with the following PTCs.
• PML50002101AA
• PML45002101AA
Table 16. Power Consumption Values II
State
Auto Halt
V_DC
2.19W
V_5
V_3
V_3S
Total Power
0.08W
0.08W
0.08W
0.01W
2.27W
2.04W
0.24W
0.01W
0.57W
0.62W
0.45W
0.00W
4.17W
3.43W
1.35W
0.05W
Quick Start
Deep Sleep
STR
1.77W
1.29W
0.04W
NOTE: These power values should be used as power supply guidelines for power management modes. They
have some guardband added for design margin. Therefore, the total power does not necessarily add up
as the sum of each power rail. "Total Power" is the sum of the individual "raw" power requirements with
guardband added.
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5.0
Electrical Specifications
The following section provides the electrical specifications for the Pentium III processor mobile
module.
5.1
System Bus Clock Signal Quality Specifications
The HCLK0 and BCLK signal names are used interchangeably.
5.1.1
BCLK DC Specifications
Table 17. BCLK DC Specifications
Symbol
Parameter
Min
Max
Unit
V
V
Input Low Voltage, BCLK
Input High Voltage, BCLK
- 0.3
2.0
0.5
V
V
IL,BCLK
2.625
IH,BCLK
NOTE: V
and V
only apply when BCLK is stopped. BCLK should be stopped in the low state. See
ILX,min
IH,max
Table 18 for the BCLK voltage range specifications when BCLK is running.
5.1.2
BCLK AC Specifications
Table 18. BCLK AC Specifications at the Processor Core Pins
T#
Parameter
Min
Nom
Max
Unit
Note
Notes 5, 6
System Bus Frequency
BCLK Period
N/A
N/A
100.0
10.0
N/A
N/A
N/A
N/A
N/A
N/A
N/A
MHz
nS
pS
nS
nS
nS
nS
Notes 2, 5, 6
BCLK Period Stability
BCLK High Time
BCLK Low Time
BCLK Rise Time
BCLK Fall Time
N/A
± 250
N/A
Notes 3, 4, 5, 6
T3:
2.85
2.55
0.175
0.175
At > 1.7V, Notes 5, 6
At > 0.7V, Notes 5, 6
0.9V ~ 1.6V, Notes 5, 6
1.6V ~ 0.9V, Notes 5, 6
T4:
T5:
T6:
N/A
0.875
0.875
NOTES:
1. All AC timings for GTL+ and CMOS signals are referenced to the BCLK rising edge at 1.25V. All CMOS
signals are referenced at 0.75V.
2. The internal core clock frequency is derived from the PSB clock. The PSB clock to core clock ratio is
determined during initialization and is predetermined by the Intel mobile module. The BCLK period allows a
+0.5 nS tolerance for clock driver variation.
3. This value is measured on the rising edge of adjacent BCLKs at 1.25V. The jitter present must be accounted
for as a component of BCLK skew between devices.
4. The clock driver’s closed loop jitter bandwidth must be set low to allow any PLL-based device to track the
jitter created by the clock driver. The -20.0 dB attenuation point, as measured into a 10.0-pF to a 2.0-pF load,
should be less than 500 kHz. This specification may be ensured by design characterization and/or measured
with a spectrum analyzer. See the CK97 Clock Synthesizer/Driver Specification (OR-1089) for further details.
5. These values are not 100% tested and are specified by design characterization as a clock driver
requirement.
6. Specifications labeled N/A are not available.
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Table 19 describes the signal quality specifications at the processor core for the PSB clock (BCLK)
signal. Figure 4 describes the signal quality waveforms for the PSB clock at the processor core pins
For proper signal termination, refer to the “Clocking Guidelines” section in the Mobile Pentium
III Processor/440BX AGPset Recommended Design and Debug Practices (RDDP-A) 100 MHz Rev.
2.0 (SC-2760).
Table 19. BCLK Signal Quality AC Specifications at the Processor Core
T#
V1
Parameter
Min
Max
Unit
Notes
V
-0.3
1.7
0.7
2.625
3.5
V
V
Notes 1, 4
Notes 1, 4
IL,BCLK
V2
V3
V4
V5
V
IH,BCLK
V
Absolute Voltage Range
-0.7
1.7
V
Undershoot, Overshoot, Note 2
Absolute Value, Notes 3, 4
Absolute Value, Notes 3, 4
IN
Rising Edge Ringback
N/A
0.7
V
Falling Edge Ringback
N/A
0.8
V
BCLK Rising/Falling Slew Rate
4.0
V/nS
NOTES:
1. On the rising edge of BCLK, there must be a minimum overshoot to 2.0V. The clock must rise monotonically
between V and 2.0V and fall monotonically between V and V
.
IL,BCLK
IL,BCLK
IH,BCLK
2. These specifications apply only when BCLK is running. See Table 17 for the DC specifications when BCLK is
stopped. BCLK may not be above V or below V for more than 50% of the clock cycle.
IH,BCLK,MAX
IL,BCLK,MIN
3. The rising edge ringback voltage specified is the minimum (rising) absolute voltage that the BCLK signal can
dip back to after it passes the V (rising) voltage limits.The falling edge ringback voltage specified
IH,BCLK,MIN
is the maximum (falling) absolute voltage that the BCLK signal can dip back to after it passes the
V
(falling) voltage limits.
IL,BCLK,MAX
4. Specifications labeled N/A are not available.
Figure 4. BCLK Waveform at the Processor Core Pins
T3
V3MAX
V4
V2MIN
V1MAX
V5
T6
T5
V3MIN T4
V0012-00
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5.2
System Power Requirements
Table 20 provides the DC power supply design criteria.
Table 20. System Power Requirements
Symbol
Parameter
DC Input Voltage
Min
Nom
Max
Unit
Notes
V
7.5
0.1
12.0
2.6
21.0
5.0
V
A
DC
I
I
I
DC Input Current
Notes 1, 2
Notes 4, 6
Notes 3, 6
DC
RMS Ripple Current
N/A
N/A
N/A
5.0
7.5
A
DC_RMS
Maximum Surge Current for V
Power Managed 5.0-V Supply
N/A
20.0
5.25
100.0
1.5
A
DC_Surge
DC
V
4.75
20.0
N/A
V
5
I
Power Managed 5.0-V Current, Operating
50.0
N/A
3.3
mA
A
5
I
Maximum Surge Current for V
Power Managed 3.3-V Supply
Notes 3, 6
Notes 3, 6
5_Surge
5
V
3.135
0.8
3.465
3.0
V
3
I
Power Managed 3.3-V Current
1.2
A
3
I
Maximum Surge Current for V
Processor I/O Ring Voltage
Processor I/O Ring Current
Processor Clock Rail Voltage
Processor Clock Rail Current
N/A
N/A
1.5
4.0
A
3_Surge
3
V
1.375
0.0
1.625
20.0
2.625
80.0
V
CPUPU
CPUPU
I
10.0
2.5
mA
V
V
2.375
24.0
CLK
I
35.0
mA Note 5
CLK
NOTES:
1. V_DC is set for 12.0V in order to determine typical V_DC current.
2. V_DC is set for 7.5V in order to determine maximum V_DC current.
3. A 20-µS duration.
4. This is V_DC dependent. See Figure 7 for data of IDC-RMS vs. V_DC.
5. These values are system dependent.
6. Specifications labeled N/A are not applicable.
5.3
Processor Core Voltage Regulation
The DC voltage regulator (DC/DC converter) supports the core voltage and I/O ring voltage. The
DC voltage regulator provides the appropriate processor core voltage, the GTL+ bus termination
voltage, the processor sideband signal pullup voltage, and the clock driver buffer voltage. Of these
voltages, only the processor sideband pullup voltage (V_CPUPU) and the clock driver buffer
voltage (V_CLK) are delivered to the system electronics.
The DC voltage range is 7.5V ~ 21.0V from the system battery or power supply for mobile
applications.
5.3.1
Voltage Regulator Efficiency
There are three voltage regulators on the mobile module. These voltage regulators generate the
core voltage used by the CPU and the voltage for the CPU I/O ring voltage. The core voltage
regulator provides the required current from the V_DC supply and its relative efficiencies are
shown in Table 21 and Figure 5. The V_CLK and Vtt voltage regulators tap the V_3 plane.
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Table 21. Vcore Power Conversion Efficiency
Vcore
Icore
(A)
Efficiency at
V_DC + 7.50V
Efficiency at
V_DC + 12.0V
Efficiency at
V_DC + 21.0V
1
2
77%
85%
87%
87%
86%
85%
84%
83%
81%
80%
79%
71%
82%
85%
86%
86%
85%
84%
83%
82%
81%
80%
63%
78%
81%
82%
83%
83%
82%
81%
81%
80%
79%
3
4
5
6
7
8
9
10
11
Figure 5. VR Efficiency Chart
VR Efficiency
90%
88%
86%
84%
82%
80%
78%
76%
74%
72%
70%
68%
66%
64%
62%
60%
V_DC = 7.5V
V_DC = 12V
V_DC = 21V
1
2
3
4
5
6
7
8
9
10 11
Icore(A)
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5.3.2
Voltage Regulator Control
The VR_ON pin on the connector allows a 3.3-V signal to control the voltage regulator. The
system manufacturer can use this signal to turn the voltage regulator on or off. VR_ON should be
controlled as a function of the same signal (SUSB#) used to control the system’s switched 5.0-V
and 3.3-V power planes. The PIIX4E/M defines Suspend B as the Power Management state in
which power is physically removed from the processor and the voltage regulator. In this state, the
SUSB# pin on the PIIX4E/M controls these power planes. The mobile module provides the
VR_PWRGD signal, which indicates that the voltage regulator power is operating at a stable
voltage level. The system manufacturer should use this signal on the system electronics to control
power inputs and to gate PWROK to the PIIX4E/M South Bridge. Table 22 provides the detailed
definitions and sequences of the voltage signals.
Table 22. Voltage Signal Definitions and Sequences
Signal
Source
Definitions and Sequences
V_DC is required to be between 7.5V and 21.0V DC and is driven by
the system electronics’ power supply. V_DC powers the Pentium III
processor mobile module DC-to-DC converter for the processor core
and I/O voltages.
V_DC
System Electronics
The mobile module cannot be hot inserted or removed while
V_DC is powered on.
V_5
V_3
System Electronics V_5 is supplied by the system electronics for the voltage regulator.
V_3 is supplied by the system electronics for the 82443BX and powers
System Electronics the mobile module’s linear regulators for generating the V_CLK and
V_CPUPU voltage rails. It stays on during suspend.
V_3S is supplied by the system electronics, and V_3S is shut off
V_3S
System Electronics
during suspend.
VR_ON is a 3.3-V signal that enables the voltage regulator circuit.
When driven active high, the voltage regulator circuit is activated. The
signal driving VR_ON should be a digital signal with a rise and fall time
VR_ON
System Electronics
of less than or equal to 1 µS. (V
= 0.4V, V
= 3.0V.)
IL (max)
IH (min)
A result of VR_ON being asserted, V_CORE is an output of the DC-
DC regulator on the mobile module and is driven to the core voltage of
the processor.
V_CORE
Module
Module
Upon sampling the voltage level of V_CORE (minus tolerances for
ripple), VR_PWRGD is driven active high. If VR_PWRGD is not
sampled active within 1 second of the assertion of VR_ON, then the
system electronics should deassert VR_ON. After V_CORE is
stabilized, VR_PWRGD will assert to logic high (3.3V). This signal
must not be pulled up by the system electronics. VR_PWRGD should
be "logically ANDed" with V_3S to generate the PIIX4E/M input signal,
PWROK. The system electronics should monitor VR_PWRGD to verify
that it is asserted high prior to the active high assertion of PIIX4E/M
PWROK.
VR_PWRGD
V_CPUPU is 1.5V. The system electronics uses this voltage to power
the PIIX4E/M-to-processor interface circuitry.
V_CPUPU
V_CLK
Module
Module
V_CLK is 2.5V. The system electronics uses this voltage to power the
HCLK[0:1] drivers for the processor clock.
The following list includes additional specifications and clarifications of the power sequence
timing and Figure 6 provides an illustration.
1. The VR_ON signal may only be asserted to a logical high by a digital signal after V_DC ≥
7.5V, V_5 ≥ 4.5V, and V_3 ≥ 3.0V.
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2. The Rise Time and Fall Time of VR_ON must be less than or equal to 1.0 µS.
3. VR_ON has its VIL (max) = +0.4V and VIH (min) = +3.0V.
4. The VR_PWRGD will get asserted to logic high (3.3V) after V_CORE is stabilized and V_DC
reaches 7.5V. This signal should not and can not be pulled up by the system electronics.
5. In the power-on process, Intel recommends to raise the higher voltage power plane first
(V_DC), followed by the lower power planes (V_5, V_3), and finally assert VR_ON after
above voltage levels are met on all rails. For powering off, follow the reverse process, i.e.
VR_ON gets deasserted, followed by the lower power planes, and finally the higher power
planes.
6. VR_ON must monotonically rise through its VIL to VIH and fall through its VIH to VIL points.
The sign of slope can not change between VIL and VIH in rising and VIH and VIL in falling.
7. VR_ON must provide an instantaneous in-rush current to the mobile module with the
following values as listed in Table 23.
Table 23. VR_ON In-rush Current
Instantaneous
DC Operating
Maximum
Typical
41.0 mA
0.2 mA
0.1 µA
0.0 µA
8. VR_ON Valid-Low Time specifies how long VR_ON needs to be low for a valid off, before
VR_ON can be turned back on again. In going from a valid on to off and then back on, the
following conditions must be met to prevent damage to the OEM system or the mobile
module:
• VR_ON must be low for 1.0 mS.
• The original voltage level requirements for turn-on must be met before assertion of
VR_ON (i.e. V_DC ≥ 7.5V, V_5 ≥ 4.5V, and V_3 ≥ 3.0V).
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Figure 6. Power Sequence Timing
V_DC
V_5
V_3
NOTE 3
0 MS MIN
0 MS MIN
V_3S
VR_ON
VR_PWRGD
V_CPUPU
NOTE 4
0 MS MIN
NOTE 5
NOTE 6
NOTE 6
V_CLK
NOTES:
1. PWROK on I/O board should be active on when VR_PWRGD is active and V_3S is good.
2. CPU_RST from I/O board should be active for a minimum of 6.0 mS after PWROK is active and PLL_STP# and CPU_STP# are inactive.
Note that PLL_STP# is an AND condition of RSMRST# and SUSB# on the PIIX4E/M.
3. This is the 5V power supplied to the MMC-2 connector. This should be the first 5.0-V plane to power up. Stays on during suspend.
4. V_DC >= 7.5V, V_5>=4.5V, V_3S>=3.0V.
5. VR_PWRGD is specified active by the module regulator within less than or equal to 6.0-mS maximum after the assertion of VR_ON.
6. V_CPUPU and V_CLK are generated on the mobile module.
5.3.3
Power Planes: Bulk Capacitance Requirements
The placement of sufficient bulk capacitance on the system electronics board is critical to the
operation of the mobile module and to ensure that the system design can accommodate future high
frequency modules. Intel has provided the maximum possible bulk capacitance on the mobile
module. However, in order to achieve proper filtering and in-rush current protection, it is
imperative that additional filtering be provided on the system electronics board. Table 24 details
the bulk capacitance requirements for the system electronics.
Note: Observe the voltage rating requirement for the capacitors on each respective voltage rail.
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Table 24 details the bulk capacitance requirements for the system electronics.
Table 24. Bulk Capacitance Requirements
Bulk Capacitance Requirements
Power
Plane
High Frequency Capacitance
Requirements
Notes
Total
Capacitance
ESR
Max
RMS Ripple
Current
V_DC
V_5
100.0 µF
100.0 µF
470.0 µF
100.0 µF
22.0 µF
2.2 µF
20.0 mΩ
100.0 mΩ
100.0 mΩ
100.0 mΩ
100.0 mΩ
N/A
3.0A~ 5.0A
1.0A
0.1 µF, 0.01 µF
0.1 µF, 0.01 µF
0.1 µF, 0.01 µF
0.1 µF 0.01 µF
0.1 µF, 0.01 µF
8200.0 pF
Notes 1,3,4,5,6
Notes 1,4,5,6
Notes 1,4,5,6
Notes 1,4,5,6
Notes 1,4,5,6
Notes 1,5,6,7
Notes 1,2,5,6,7
V_3
1.0A
V_3S
N/A
VCC_AGP
V_CPUPU
V_CLK
1.0A
N/A
10.0 µF
N/A
N/A
8200.0 pF
NOTES:
1. Placement of above capacitance requirements should be located near the connector.
2. V_CLK filtering should be located next to the system clock synthesizer.
3. The Ripple current specification depends on the V_DC input for the mobile module. See Figure 7 below.
4. If Tantalum* Capacitors are used, a 50% voltage derating practice must be observed. For example, a 5.0-V
rail requires a 10.0-V rated capacitor.
5. In order to reduce ESR, Intel recommends the use of multiple bulk capacitors rather than a single large
capacitor.
6. Intel strongly recommends that system manufacturers pay close attention to capacitor design considerations.
Specifically, the "Capacitance vs. Temperature De-rating Curve," "Capacitance vs. Applied DC Voltage De-
rating Curve," and the "Capacitance vs. Frequency De-rating Curve." Some capacitor dielectrics are
particularly susceptible to these conditions, for example Y5V ceramic capacitors.
7. Specifications labeled N/A are not available.
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Figure 7 shows the dependence of V_DC ripple current on V_DC.
Figure 7. V_DC Ripple Current
V_DC Input Ripple Current vs. V_DC Voltage
6.00
5.50
5.00
4.50
4.00
3.50
3.00
2.50
2.00
1.50
1.00
0.50
0.00
7
8
9
10 11 12 13 14 15 16 17 18 19 20 21
V_DC(V)
5.3.4
System Power Supply Protection Guidelines
DC Power System Protection
5.3.4.1
The recommended DC Power System Protection consists of the following:
• A DC Power Supply capable of delivering 7.5V to 21.0V to the mobile module
• An Overcurrent Protection circuit providing a means to limit the maximum current available to
the system
• A Slew Rate Control circuit providing a controlled voltage slew rate at turn on, which provides
protection for components sensitive to fast voltage rise times
• An Undervoltage Lockout circuit to protect against potentially damaging high currents, which
might be encountered if the DC Power Supply voltage is too low
• An Overvoltage Lockout circuit providing protection from potentially damaging high DC
Power Supply voltages
• Bulk Decoupling Capacitors providing filtering and a reservoir of energy that can give a faster
transient response than the power supply
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Figure 8. V_DC Power System Protection Block Diagram
V_DC Power
Supply
Overcurrent
Protection
Slew Rate
Control
Bulk
Decoupling
Capacitors
Module
(See Table 19)
(See Section 5.3.4.3)
(See Section 5.3.4.5)
Undervoltage
Lockout
(See Section 5.3.4.6)
Overvoltage
Lockout
(See Section 5.3.4.7)
5.3.4.2
5.3.4.3
V_DC Power Supply
The power supply must be able to deliver 7.5V to 21.0V to the mobile module, measured at the
mobile module.
Overcurrent Protection
The overcurrent protection circuit provides a way to limit current drawn by the mobile module.
Under normal operating conditions, I_DC should not be expected to exceed 3.0A at V_DC = 7.5V.
To allow for component variations and margining issues, a reasonable I_DC current limit would be
6.0A.
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Figure 9. Overcurrent Protection Circuit
Over Current Protection
Slew Rate Control
Si4435DY
M1
V_DC
R1
Power Supply
+
-
R4
V_DC
R16
C9
R13
Q1
R12
U1B
R20
R2
M3
2.5V
C18
2N2222A
2N7000
LM4040
R33
R14
V_DC
R35
U1A
R36
NOTE: U1B must be able to operate with inputs near the V_DC
rail. Consider the LMC6762.
At the other end of the V_DC input range, the current will be somewhat less. At 14.0V, for
example, the corresponding power could be produced with only 3.0A. In this example, a
comparator, U1A, will be used to sense when V_DC is over 14.0V and will shift the current limit
from 6.0A to 3.0A.
• Let I_DC(limit)= 6.0A
• Let I_DC(limit2)= 3.0A
• Let b(Q1)= 100
• Let R1=5.0 mΩ= 0.005Ω
• Let R12= 100.0Ω
• Let R13= 100.0Ω
• Let V(R14)≈ 1.8V
• Let I(R20)≈ 100.0 µA
• Let C36= 2.0K
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Figure 10. Current Shift Model
V_DC
R35
U1A +in
R36
5.3.4.4
Current Limit Shift Point
Comparator U1A should switch when the non-inverting input is equal to the 2.5-V reference on the
inverting input, or when the voltage applied to V_DC is equal to the selected switch point and the
voltage dropped across R36 is 2.5V. This drop should occur when V_DC= 14.0V.
Equation 1.
(V_DC Vref)
Vref
(14 2.5)
2.5
R35
R35
R36
2000
(The nearest standard 1% value is 9.01 kΩ.)
Comparator U1A will pull its output low when V_DC falls below 14.0V. This drop will effectively
put R33 in parallel with R14.
When power is initially applied to the circuit, C18 charges up to 2.5V through R20. This slowly
rising voltage is applied to the base of the current source, Q1. The voltage on R14 is approximately
2.5V minus the base-emitter drop of about 0.7V (at 25°C): V(R14) ≈ 1.8V. Q1 is a 2N2222A with a
moderate β of about 100. Therefore, the current through R13 is approximately equal to the current
through R14.
The charging of C18, provides a small increment of delay as U1 will not allow R4 to pull up the
Gate of M3 until Q1 has pulled the non-inverting input of U1 down slightly.
The voltage developed across R1 is a function of the load.
Equation 2.
V(R1)= I_DC*R1
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If the maximum I_DC expected is 3.0A, consider setting the I_DC Current Limit at 6.0A. If the
Current Sense resistor, R1, is selected to be 5.0 mΩ (0.005Ω), the maximum voltage developed
across this resistor can be calculated. See below.
Consider now the case where V_DC is above 14.0V.
Equation 3.
I_DC(limit)*Rsense= 3.0A*5E-3= 15.0 mV)
The Offset voltage applied to the inverting input of the comparator, U1B, should then be 15.0 mV.
If R13 is selected to be 100.0Ω, the current can then be calculated as shown in Equation 4 below.
Equation 4.
Ioffset= 15.0 mV/100Ω= 150.0 µA
Note: For a successful design, the input offset of the comparator must be considered. One option is that
the design offset is at least ten times greater than the device offsets.
The value of R14 can now be calculated as shown in Equation 5 below.
Equation 5.
R14= 1.8V/150.0 µA= 12.0 kΩ
(The nearest 1% value is 12.1K.)
Consider now the case when V_DC drops below 14.0V and the current limits shift to 6.0A.
Equation 6.
I_DC(limit)*Rsense= 6.0A*5E-3= 30.0 mV
The Offset voltage applied to the inverting input of the comparator, U1B, should then be 30 mV. If
R13 is selected to be 100Ω, the current can then be calculated as shown in Equation 7 below.
Equation 7.
Ioffset= 30.0 mV/100Ω= 300.0 µA
The value of parallel combination of R14 and R33 can now be calculated as shown in Equation 8
below.
Equation 8.
Rcombo= 1.8V/300.0 µA= 6.0 kΩ
R14 is a 12.0-K resistor. If R33 is also a 12.0-K resistor, the parallel combination will be 6.0K.
In R20, the LM4040-2.5 has a very wide operating current range from 60.0 µA to 15.0 µA. In order
to provide the Current Source Base drive you will need Equation 9.
Equation 9.
Ibase≈ Ic/b= 300.0 µA/100= 3.0 µA
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If selected for I(R20), 100 µA would be adequate for the Reference and Current Source Base drive.
Since both of these currents must be satisfied at the low-power supply margin, a V_DC of 7.5V
will be assumed.
Equation 10.
R20 = (V_DC-Vref)/I(R20) = (7.5-2.50)/100.0 µA= 50.0 kΩ
(To allow for component tolerances, 51.0 kΩ is recommended.)
5.3.4.5
Slew Rate Control
The Slew Rate Control regulates the rate that the power supply voltage is applied to the system.
• Let the Threshold voltage of M1, Vt = -1.0V
• Let M1 VGS(sat) = -2.4V, also denoted as Vsat
• Let R16 = 100.0 kΩ
• Let t_delay = 500.0 µS
• Let Ctotal = The sum or the Bulk capacitors + the sum of the module capacitors = 5 X 22.0 µF
+ 2 X 4.7 µF= 119.4 µF
M1 is a low RDS(on) P-Channel MOSFET such as the Siliconix* Si4435DY. When the power
supply voltage is applied and increased to a value that exceeds the Lockout value, (7.5V will be
used in this example), the Undervoltage Lockout circuit, allows R4 to pull up the gate of M3 to
start a turn-on sequence. M3 pulls its drain toward ground, forcing current to flow through R2. M1
will not start to source any current until after t_delay, with t_delay defined as shown in Equation 11
and Equation 12 below.
Equation 11.
Vt
.
.
t_delay
R2 C9 ln 1
V_DC Vg
Equation 12.
R16
Vgs
V_DC
R16 R2
The published minimum threshold of the Si4435DY is a VGS of -1.0V, i.e. C9 must charge to 1.0V
before M1 starts to turn on. The delay, t_delay, is the time required to charge C9 to 1.0V.
Assuming a negligible voltage drop across M3, when M3 is ON, the voltage on the Gate of M1,
VG, with respect to ground, is the voltage developed across R2: VG≡ V(R2). If a minimum steady-
state bias on M1 is -4.5V, this will be the voltage dropped across R16. At the low end of the V_DC
margin, i.e. 7.5V, then VG can be derived from Equation 13 below.
Equation 13.
VG = V_DC+VGS = 7.5V- 4.5V = 3.0V (with respect to ground)
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Equation 14.
.
Vg R16
,
R2
R2 = 66.67 k Ω
V_DC Vg
(The nearest standard 1% value is 66.5 kΩ. The example will continue with R2= 66.5 kΩ.)
Rearranging Equation 8 to solve for C9 yields the following result, as shown in Equation 15.
Equation 15.
t_delay
Vt
V_DC Vg
C9
.
R2 ln 1
Now a value for C9 can be calculated. See Equation 16 below.
Equation 16.
C 9= 0.354 µF
(A close standard value of 0.33 µF will yield a t_delay of 466.0 µS.)
The ramp-up time, t_ramp, is defined as shown in Equation 17 below.
Equation 17.
Vsat
Vgs
.
.
t_ramp
R2 C9 ln 1
t_delay
If M1 has a VGS(sat) of -2.4V, then see Equation 18 below.
Equation 18.
t_ramp = 948.8 µS
The maximum current during the power-up ramp is shown in Equation 19 below.
Equation 19.
V_DC
d
dt
.
Ctotal
≈
Imax Cto tal
v
t_ramp
If the total capacitance, Ctotal on the V_DC bus, is 119.4 µF, then see Equation 20 below.
Equation 20.
Imax = 0.994A
From the values assumed and calculated, t_delay = 466.0 µS, t_ramp = 949.0 µS, and Imax = 944
mA.
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5.3.4.6
Undervoltage Lockout
The circuit below shows the Undervoltage Lockout portion of the V_DC Supply circuit. This
circuit protects and locks out the applied voltage to the mobile module to prevent an accidental
turn-on at low V_DC supply voltages.
Warning: A low voltage applied to the mobile module could result in destructive current levels.
Figure 11. Undervoltage Lockout
V_DC_A
Let V_DC_UVlock=7.5V
Let R17=10 kΩ
Let R25=1 mΩ
Let VCEsat= 0.3V
Let Vref=2.5V
R4
M3 Gate
V_DC
Vref
2.5V
R25
V_DC
R17
R18
LM339
Undervoltage Lockout
The output of the LM339 comparator is an open-collector and is low when the applied voltage at
V_DC is less than 7.5V, which holds the Gate of M3 low. Consequently, the Slew Rate Controller
is not allowed to turn on. The 2.5-V reference, Vref, voltage is derived from D7 in Figure 9. When
the non-inverting input of the comparator exceeds Vref, 2.5V, the comparator trips and allows its
output to go to a High Z state. The Gate of M3 can then be pulled up by R4, starting the controlled
Power-up Slew.
The model in Figure 12 will be used to calculate the Undervoltage Lockout trip point.
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Figure 12. Undervoltage Lockout Model
V_DC
R17
2.5V
R25
R18
+
VCEsat
Undervoltage Lockout Model
VCEsat is the saturation voltage of the comparator output transistor.
The comparator trip point voltage can be calculated with Equation 21.
Equation 21.
Vref Vref VCEsat
V_DC_UVlock Vref
R17
R18
R25
If power to the mobile module is to be held off until V_DC exceeds 7.5V, Equation 21 can be
rearranged to solve for R18.
Equation 22.
.
.
Vref R17 R25
R18
.
.
R25 (V_DC_UVlock Vref) R17 (Vref VCEsat)
A value for R18 can be determined by plugging these values into Equation 23.
Equation 23.
R18 = 11.0 kΩ
(4.99 kΩ is a standard 1% resistor value, which would provide lockout below 7.532V.)
5.3.4.7
Overvoltage Lockout
The mobile module operates with a maximum input voltage of 21.0V. This circuit can be set to lock
out the input voltage if it exceeds the desired input.
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Figure 13. Overvoltage Lockout
V_DC_A
Ω
Let R4=100K
Let R24=100K
R4
Vref
Ω
Let R26=1M
Ω
Let R27=1K
2.5V
M3 Gate
V_DC
R27
R26
V_DC
R24
R23
LM339
Overvoltage Lockout
The LM339 comparator is an open-collector output and is pulled low when the applied voltage at
V_DC is too high, thus disabling the Slew-rate circuit.
The model in Figure 14 below will be used for component calculations.
Figure 14. Overvoltage Lockout Model
V_DC
V_DC_A
R4
R24
Vinv
R26
R23
Vnoninv
R27
Overvoltage Lockout Model
Vref
Assume that the desired V_DC Overvoltage Lockout is 21.0V. Using Equation 24, the input to the
non-inverting input of the OV Lockout comparator can be calculated with the following equations.
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Equation 24.
.
R27 (V_DC_OVlock Vref)
R4 R26 R27
Vnoninv Vref
Equation 25.
Equation 26.
Vnoninv= 2.517V
.
(V_DC_OVlockR23)
Vinv
R23 R24
The output of the OV Lockout comparator will become active and pull down when the inverting
input becomes greater than the 2.517V input on the non-inverting input. Equation 26 can be
rearranged to solve for R23.
Equation 27.
.
R24 Vinv
R23
V_DC_OVlock Vinv
The OV Lockout comparator trip point is defined by Vinv = Vnoninv = 2.517V. Equation 28
provides a solution for R23.
Equation 28.
R23= 13.618 kΩ
(The nearest standard 1% value is 13.7 kΩ.)
If V_DC exceeds 6.0V, the voltage on the OV Lockout comparator inverting input will exceed
2.517V causing the comparator to trip, pulling its output low and disabling the Power Skew
Control circuit which, in turn, will disconnect V_DC from the mobile module.
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Figure 15. Recommended Power Supply Protection Circuit for the System Electronics
Slew Rate Control
Over Current Protection
V_DC
Input Bulk Decoupling Capacitors
MMO Processor Module
Si4435DY
R1
C Adaptor
+
0.3
1M
R4
V_DC
0.3
0.3
0.3
0.3
R16
0.3
C9
0.3
R13
-
R12
R20
27uF
27uF
27uF
27uF
27uF
4.7uF
R2
M3
4.7uF
2.5V
LM339
2N2222A
2N7000
C18
LM4040
V_DC
R14
V_DC
Components values assumed and calculated
V_DC
R33
R25
2.5V
R35
R17
R18
V_DC
R1
R2
R4
5m
R20 20 k
,
Ω
Ω ±
5%
5.62 kΩ, ± 1%
100 kΩ, ± 1%
R23 71.5 kΩ, ± 1%
R24 100 kΩ, ± 1%
R25 1M, ± 5%
LM339
LM339
R36
Under
Voltage Lockout
R12 100Ω, ± 1%
R13 100 1%
R14 12.1 kΩ, ± 1%
R16 100 kΩ, ± 1%
R17 10 kΩ, ± 1%
R18 11 kΩ, ± 1%
,
R26 1M, 5%
Ω ±
±
V_DC
R27 1 kΩ, ± 1%
R33 12.1 kΩ, ± 1%
R35 9.1 kΩ, ± 1%
R36 2 kΩ, ± 1%
R27
R26
V_DC
R24
LM339
C9
0.33 µF
R23
C18 0.1 µF
Over Voltage Lockout
Figure 16. Simulation of V_DC Voltage Skew
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5.4
Active Thermal Feedback
Table 25. Thermal Sensor SMBus Address
Function
SMBus Address
Thermal Sensor
1001 110
5.5
Thermal Sensor Configuration Register
The configuration register of the thermal sensor controls the operating mode (Auto Convert vs.
Standby) of the device. Since the processor temperature varies dynamically during normal
operation, Auto Convert mode should be used exclusively to monitor processor temperature. Table
26 shows the format of the configuration register. If the RUN/STOP bit is low, then the thermal
sensor enters Auto Convert mode. If the RUN/STOP bit is set high, then the thermal sensor
immediately stops converting and enters the Standby mode. The thermal sensor will still perform
temperature conversions in Standby mode when it receives a one-shot command. However, the
result of a one-shot command during Auto Convert mode is not guaranteed. Intel does not
recommend using the one-shot command to monitor temperature when the processor is active, only
Auto Convert mode should be used. The thermal sensor can be configured in various interface
modes for temperature sampling. Intel recommends interfacing the thermal sensor using Interrupt
mode. For more detailed information regarding interface methods, please see the Intel Mobile
Module Thermal Diode Temperature Sensor Application Note available through your Intel Field
Representative.
Table 26. Thermal Sensor Configuration Register
Bit
Name
Reset State
Function
Masks SMBALERT# when high
7 MSB MASK
0
Standby mode control bit. If low, the device enters Auto Convert
mode. If high, the device immediately stops converting and enters
Standby mode where the one-shot command can be performed.
6
RUN/STOP
RFU
0
0
5-0
Reserved for future use
NOTE: All RFU bits should be written as “0” and read as “don’t care” for programming purposes.
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6.0
Mechanical Specification
This section provides the physical dimensions of the Pentium III processor mobile module.
6.1
Module Dimensions
Figure 17 shows the board dimensions and the connector orientation.
Figure 17. Board Dimensions and MMC-2 Connector Orientation
Module Mechanical X-Y-Z Dimensions and Thermal
Attach Points
Unless otherwise specified:
Tolerances
Angles
.X
± 0.5°
± 0.2
.XX
.XXX
± 0.15
± 0.075
* All Dimensions are in mm
6.1.1
Pin 1 Location of the MMC-2 Connector
Figure 18 shows the location of pin 1 of the 400-pin connector.
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Figure 18. Board Dimensions and MMC-2 Connector—Pin 1 Orientation
6.1.2
Printed Circuit Board
Figure 19 shows the Pentium III processor mobile module associated minimum and maximum
thickness of the printed circuit board (PCB). The range of PCB thickness allows for different PCB
technologies to be used with current and future Intel mobile modules.
Note: The system manufacturer must ensure that the mechanical restraining method and/or system-level
EMI contacts are able to support this range of PCB for compatibility with future Intel mobile
modules.
Figure 19. Printed Circuit Board Thickness
Min: 0.90 mm
Max: 1.10 mm
Printed Circuit Board
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6.1.3
Height Restrictions
Figure 20 shows the mechanical stack-up and the associated component clearance requirements.
This is the module keep-out zone and should not be entered. The system manufacturer establishes
board-to-board clearance between the module and the system electronics by selecting one of three
mating connectors available in heights of approximately 4 mm, 6 mm, and 8 mm. The three sizes
provide flexibility in choosing the system electronics components between the two boards.
Information on these connectors can be obtained from your Intel sales representative.
Figure 20. Keep-out Zone
Note 3
Note 3
NOTES:
1.
2.
All values are nominal unless otherwise specified.
3D CAD model (PRO/E Native) Available upon
request.
3.
These dimensions have changed.
6.2
Thermal Transfer Plate
The thermal transfer plates (TTP) provide heat dissipation on the mobile Pentium III processor and
the 82443BX. The TTP may vary on different generations of Intel mobile modules. The TTP
provides the thermal attach point, where a system manufacturer can transfer heat through the
notebook system using a heat pipe, a heat spreader plate, or a thermal solution. Attachment
dimensions for the thermal interface block to the TTP are provided in Figure 21, Figure 22, and
Figure 23. The TTP on the mobile module is designed to be a high efficiency spreader. To fully
take advantage of the mobile module thermal design and optimize the system thermal performance,
the contact area (Ac) needs to be a minimum of 30 mm x 30 mm. While it crucial to maximize the
contact area, it is equally important to ensure that the contact area and/or the mobile module is free
from warpage in an assembled configuration.
Warning: If warpage occurs, the thermal resistance of the mobile module could be adversely affected.
When attaching a mating block to either TTP, Intel recommends that a thermal elastomer be used as
an interface material. This material reduces the thermal resistance. The OEM thermal interface
block should be secured to the CPU TTP with M2 screws using a maximum torque of 1.5 Kg*cm
to 2.0 Kg*cm (equivalent to 0.147 N*m to.197 N*m). The thread length of the M2 screws should
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be 2.25-mm gageable thread (2.25-mm minimum to 2.80-mm maximum). The mobile module is
designed to ensure that the thermal resistance between the processor die center and a point directly
above on the TTP surface is ≤ to 0.35° C/W, under the following set of conditions.
• RTTP-a = TTP (center point) to ambient = ~2.4° C/W
• Ac = Contact area centered between the two TTP attach points = 30 mm x 30 mm.
Figure 21. 82443BX Thermal Transfer Plate (Reference Only)
BX TTP
Rivets for PCB Mounting
Figure 22. 82443BX Thermal Transfer Plate Detail
3.150
1.000 0.89
±
3.569
6.280
1.050
NOTE: All tolerances are ± 0.015 mm unless otherwise noted.
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Figure 23. CPU Thermal Transfer Plate (Reference Only)
6.3
Module Physical Support
6.3.1
Module Mounting Requirements
Three mounting holes are available for securing the module to the system base or the system
electronics. See Figure 17 for mounting hole locations. These hole locations and board edge
clearances will remain fixed for all Intel mobile modules. All three mounting holes should be used
to ensure long term mechanical reliability and EMI integrity of the system.
The board edge clearance includes a 0.762-mm (0.030-inches) wide EMI containment ring around
the perimeter of the mobile module. This ring is on each layer of the PCB and is grounded. The
hole patterns also have a plated surrounding ring to use a metal standoff for EMI shielding
purposes. Standoffs should be used to provide support for the installed mobile module. However,
the warpage of the baseboard can vary and should be calculated into the final dimensions of the
standoffs used. All calculations can be made with the Intel MMC-2 Standoff/Receptacle Height
Spreadsheet. Information on this spreadsheet can be obtained from your local Intel Field
Representative.
Figure 24 shows the standoff support hole details, the board edge clearance, and the dimensions of
the EMI containment ring. No components are placed on the board in the keep-out area.
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Pentium III Processor Mobile Module MMC-2
Figure 24. Standoff Holes, Board Edge Clearance, and EMI Containment Ring
Hole detail, 3 places
3.81+/-0.19 mm
+ 0.050 mm
2.413 mm
- 0.025 mm
hole diameter
4.45 mm diameter grounded ring
1.27+/- 0.19 mm board edge to EMI ring
0.762 mm width of EMI containment ring
2.54+/-0.19 mm keep-out area
3.81+/-0.19 mm board edge to hole centerline
6.3.2
Module Weight
The Pentium III processor mobile module weighs approximately 56 grams.
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7.0
Thermal Specification
7.1
Thermal Design Power
The power handling capability of the system thermal solution may be reduced to less than the
recommended typical Thermal Design Power (TDP) as shown in Table 27 with the implementation
of firmware/software control or "throttling” that reduces the CPU power consumption and
dissipation. The typical TDP is the typical power dissipation under normal operating conditions at
nominal V_CORE (CPU power supply) while executing the worst case power instruction mix. This
includes the power dissipated by all of the relevant components. During all operating
environments, the processor junction temperature, TJ, must be within the specified range of 0° C to
100 ° C.
Table 27. Thermal Design Power Specification
Typical
450 MHz
Typical
500 MHz
Symbol
Parameter
Notes
Module = core + 82443BX +
voltage regulator
TDP
Module Thermal Design Power
14.1W
15.0W
Module
NOTES:
1. During all operating environments, the processor temperature, T , must be within the special range of 0 °C to
j
100°C.
2. TDP
is a thermal-solution design reference point for thermal solution readiness for total module power.
Module
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Pentium III Processor Mobile Module MMC-2
8.0
Labeling Information
Intel mobile modules are tracked in two ways. The first is by the product tracking code (PTC). Intel
uses the PTC label to determine the assembly level of the module. Figure 25 shows where the PTC
can be found on the module. The PTC contains 13 characters and provides the following
information.
Example: PML50002001AA
Key: AABCCCDDEEEFFF
Definition:
AA
B
-
-
-
-
-
-
Processor Module = PM
Pentium III processor mobile module = L
Speed Identity = 450, 500
CCC
DD
EEE
FF
Cache Size = 02 (256K)
Notifiable Design Revision (Start at 001)
Notifiable Processor Revision (Start at AA)
Note: For other Intel mobile modules, the second field (B) is defined as:
Pentium II Processor Mobile Module (MMC-1) = D
Pentium II Processor Mobile Module (MMC-2) = E
Pentium II Processor Mobile Module With On-die Cache (MMC-1) = F
Pentium II Processor Mobile Module With On-die Cache (MMC-2) = G
Celeron Processor Mobile Module (MMC-1) = H
Celeron Processor Mobile Module (MMC-2) = I
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Figure 25. Product Tracking Code
Intel Assembly Identification
Intel Serial Number
PBA XXXXXX-XXX
XXXXXXXXXXXXX
ISYWW6666
Product Tracking Code
Secondary Side of the Module
The second tracking method is by an OEM generated software utility. Four strapping resistors
located on module determine its production level. If connected and terminated properly, up to 16
module-revision levels can be determined. An OEM generated software utility can then read these
ID bits with CPU IDs and stepping IDs to provide a complete module manufacturing revision level.
For current PTC and module ID bit information, please refer to the latest Intel mobile module
product change notification (PCN) letter, which can be obtained from your local Intel Field
Representative.
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Pentium III Processor Mobile Module MMC-2
9.0
Environmental Standards
The environmental standards are defined in Table 28.
Table 28. Environmental Standards
Parameter
Condition
Specification
Non-operating
Operating
-40 °C to 85 °C
0 °C to 55 °C
Temperature Cycle
Humidity
Unbiased
85% relative humidity at 55°C
V_5
V_3
5.0V ± 5%
3.3V ± 5%
Voltage
Non-operating
Unpackaged
Packaged
Half Sine, 2G, 11 mS
Trapezoidal, 50G, 11 mS
Shock
Inclined impact at 5.7 feet/S
Half Sine, 2 mS at 36 inches simulated free fall
Packaged
Unpackaged
Packaged
Packaged
5 Hz to 500 Hz, 2.2-gRMS random
10 Hz to 500 Hz, 1.0 gRMS
Vibration
11,800 impacts 2 Hz to 5 Hz (low frequency)
Non-powered test of the mobile module only for non-
ESD Damage
Human Body Model catastrophic failure. The module is tested at 2 kV and then
inserted in a system for functional test.
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