INTEL FWPXA270C5E416

Intel® PXA270 Processor
Electrical, Mechanical, and Thermal Specification
Data Sheet
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High-performance processor:
— Intel XScale® microarchitecture with
Intel® Wireless MMX™ Technology
— 7 Stage pipeline
— 32 KB instruction cache
— 32 KB data cache
— 2 KB “mini” data cache
— Extensive data buffering
256 Kbytes of internal SRAM for high
speed code or data storage preserved
during low-power states
High-speed baseband processor interface
(Mobile Scalable Link)
Rich serial peripheral set:
— AC’97 audio port
— I2S audio port
— USB Client controller
— USB Host controller
— USB On-The-Go controller
— Three high-speed UARTs (two with
hardware flow control)
— FIR and SIR infrared communications
port
Hardware debug features — IEEE JTAG
interface with boundary scan
Hardware performance-monitoring
features with on-chip trace buffer
Real-time clock
Operating-system timers
LCD Controller
Universal Subscriber Identity Module
interface
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Low power:
— Wireless Intel Speedstep® Technology
— Less than 500 mW typical internal
dissipation
— Supply voltage may be reduced to
0.85 V
— Four low-power modes
— Dynamic voltage and frequency
management
High-performance memory controller:
— Four banks of SDRAM: up to 104 MHz
@ 2.5V, 3.0V, and 3.3V I/O interface
— Six static chip selects
— Support for PCMCIA and Compact
Flash
— Companion chip interface
Flexible clocking:
— CPU clock from 104 to 624 MHz
— Flexible memory clock ratios
— Frequency changes
— Functional clock gating
Additional peripherals for system
connectivity:
— SD Card / MMC Controller (with SPI
mode support)
— Memory Stick card controller
— Three SSP controllers
— Two I2C controllers
— Four pulse-width modulators (PWMs)
— Keypad interface with both direct and
matrix keys support
— Most peripheral pins double as GPIOs
Order Number 280002-006
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ESTOPPEL OR OTHERWISE, TO ANY INTELLECTUAL PROPERTY RIGHTS IS GRANTED BY THIS DOCUMENT. EXCEPT AS PROVIDED IN
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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, 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 PXA270
processor 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.
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*Other names and brands may be claimed as the property of others.
Copyright © Intel Corporation, 2006. All Rights Reserved.
ii
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Contents
Contents
1
Introduction .........................................................................................................1-1
1.1
About This Document.................................................................................1-1
1.1.1 Number Representation ................................................................1-1
1.1.2 Typographical Conventions ...........................................................1-1
1.1.3 Applicable Documents...................................................................1-2
2
Functional Overview ...........................................................................................2-1
3
Package Information...........................................................................................3-1
3.1
3.2
3.3
3.4
3.5
4
Pin Listing and Signal Definitions .....................................................................4-1
4.1
4.2
4.3
4.4
4.5
5
Ball Map View.............................................................................................4-2
4.1.1 13x13 mm VF-BGA Ball map ........................................................4-2
4.1.2 23x23 mm PBGA Ball map............................................................4-6
Pin Use.......................................................................................................4-9
Signal Types.............................................................................................4-27
Memory Controller Reset and Initialization...............................................4-28
Power-Supply Pins ...................................................................................4-29
Electrical Specifications.....................................................................................5-1
5.1
5.2
5.3
5.4
5.5
5.6
5.7
6
Package Information ..................................................................................3-1
Processor Materials....................................................................................3-6
Junction To Case Temperature Thermal Resistance.................................3-7
Processor Markings....................................................................................3-7
Tray Drawing ..............................................................................................3-8
Absolute Maximum Ratings........................................................................5-1
Operating Conditions..................................................................................5-1
5.2.1 Internal Power Domains ................................................................5-6
Power-Consumption Specifications............................................................5-6
DC Specification.........................................................................................5-9
Oscillator Electrical Specifications............................................................5-10
5.5.1 32.768-kHz Oscillator Specifications ...........................................5-10
5.5.2 13.000-MHz Oscillator Specifications..........................................5-12
CLK_PIO and CLK_TOUT Specifications ................................................5-13
48 MHz Output Specifications ..................................................................5-14
AC Timing Specifications...................................................................................6-1
6.1
6.2
AC Test Load Specifications ......................................................................6-1
Reset and Power Manager Timing Specifications......................................6-2
6.2.1 Power-On Timing Specifications ...................................................6-2
6.2.2 Hardware Reset Timing.................................................................6-4
6.2.3 Watchdog Reset Timing ................................................................6-4
6.2.4 GPIO Reset Timing .......................................................................6-4
6.2.5 Sleep Mode Timing .......................................................................6-6
6.2.6 Deep-Sleep Mode Timing..............................................................6-6
Electrical, Mechanical, and Thermal Specification
iii
Intel® PXA270 Processor
Contents
6.3
6.4
6.5
6.6
6.7
6.8
6.9
6.10
6.2.7 Standby-Mode Timing ...................................................................6-9
6.2.8 Idle-Mode Timing...........................................................................6-9
6.2.9 Frequency-Change Timing............................................................6-9
6.2.10 Voltage-Change Timing...............................................................6-10
GPIO Timing Specifications .....................................................................6-10
Memory and Expansion-Card Timing Specifications................................6-11
6.4.1 Internal SRAM Read/Write Timing Specifications .......................6-11
6.4.2 SDRAM Parameters and Timing Diagrams.................................6-11
6.4.3 ROM Parameters and Timing Diagrams .....................................6-17
6.4.4 Flash Memory Parameters and Timing Diagrams.......................6-22
6.4.5 SRAM Parameters and Timing Diagrams ...................................6-32
6.4.6 Variable-Latency I/O Parameters and Timing Diagrams.............6-35
6.4.7 Expansion-Card Interface Parameters and Timing Diagrams.....6-39
LCD Timing Specifications .......................................................................6-42
SSP Timing Specifications .......................................................................6-44
JTAG Boundary Scan Timing Specifications............................................6-45
Intel® Quick Capture Interface AC Timing ...............................................6-47
MultiMediaCard Timing Specifications .....................................................6-48
Secure Digital (SD/SDIO) Timing .............................................................6-48
Figures
2-1 Intel® PXA270 Processor Block Diagram, Typical System................................2-2
3-1 13x13mm VF-BGA Intel® PXA270 Processor Package, top view .....................3-1
3-2 13x13mm VF-BGA Intel® PXA270 Processor Package, bottom view ...............3-2
3-3 13x13mm VF-BGA Intel® PXA270 Processor Package, side view ...................3-3
3-4 VF-BGA Product Information Decoder...............................................................3-3
3-5 23x23 mm PBGA Intel® PXA270 Processor Package (Top View) ....................3-4
3-6 23x23 mm PBGA Intel® PXA270 Processor Package (Bottom View) ...............3-4
3-7 23x23 mm PBGA Intel® PXA270 Processor Package (Side View) ...................3-5
3-8 PBGA Product Information Decoder ..................................................................3-5
3-9 13x13mm VF-BGA Intel® PXA270 Processor Package, bottom view ...............3-6
3-10Intel® PXA270 Processor Production Markings, (Laser Mark on Top Side)......3-7
4-1 13x13 mm VF-BGA Ball Map, Top View (upper left quarter) .............................4-2
4-2 13x13 mm VF-BGA Ball Map, Top View (upper right quarter) ...........................4-3
4-3 13x13 mm VF-BGA Ball Map, Top View (bottom left quarter) ...........................4-4
4-4 13x13 mm VF-BGA Ball Map, Top View (bottom right quarter) ........................4-5
4-5 23x23 mm PBGA Ball Map, Top View (Upper Left Quarter) ..............................4-6
4-6 23x23 mm PBGA Ball Map, Top View (Upper Right Quarter)............................4-7
4-7 23x23 mm PBGA Ball Map, Top View (Lower Left Quarter) ..............................4-8
4-8 23x23 mm PBGA Ball Map, Top View (Lower Right Quarter)............................4-9
6-1 AC Test Load .....................................................................................................6-1
6-2 Power On Reset Timing .....................................................................................6-3
6-3 Hardware Reset Timing .....................................................................................6-4
6-4 GPIO Reset Timing ............................................................................................6-5
6-5 Sleep Mode Timing ............................................................................................6-6
6-6 Deep-Sleep-Mode Timing ..................................................................................6-7
6-7 SDRAM Timing ................................................................................................6-14
6-8 SDRAM 4-Beat Read/4-Beat Write, Different Banks Timing............................6-15
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Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Contents
6-9 SDRAM 4-Beat Write/4-Beat Write, Same Bank-Same Row Timing ...............6-16
6-10 SDRAM Fly-by DMA Timing.............................................................................6-17
6-11 32-Bit Non-burst ROM, SRAM, or Flash Read Timing .....................................6-19
6-12 32-Bit Burst-of-Eight ROM or Flash Read Timing ............................................6-20
6-13 Eight-Beat Burst Read from 16-Bit Burst-of-Four ROM or Flash Timing..........6-21
6-14 16-bit ROM/Flash/SRAM Read for 4/2/1 Bytes Timing ....................................6-22
6-15 Synchronous Flash Burst-of-Eight Read Timing ..............................................6-25
6-16 Synchronous Flash Stacked Burst-of-Eight Read Timing ................................6-26
6-17 First-Access Latency Configuration Timing......................................................6-27
6-18 Synchronous Flash Burst Read Example.........................................................6-29
6-19 32-Bit Flash Write Timing .................................................................................6-30
6-20 32-Bit Stacked Flash Write Timing ...................................................................6-31
6-21 16-Bit Flash Write Timing .................................................................................6-32
6-22 32-Bit SRAM Write Timing ...............................................................................6-34
6-23 16-bit SRAM Write for 4/2/1 Byte(s) Timing .....................................................6-35
6-24 32-Bit VLIO Read Timing .................................................................................6-37
6-25 32-Bit VLIO Write Timing..................................................................................6-38
6-26 Expansion-Card Memory or I/O 16-Bit Access Timing.....................................6-40
6-27 Expansion-Card Memory or I/O 16-Bit Access to 8-Bit Device Timing ............6-41
6-28 LCD Timing Definitions.....................................................................................6-42
6-29 SSP Master Mode Timing Definitions...............................................................6-44
6-30 Timing Diagram for SSP Slave Mode Transmitting Data to an External
Peripheral .........................................................................................................6-44
6-31 Timing Diagram for SSP Slave Mode Receiving Data from External
Peripheral .........................................................................................................6-45
6-32 JTAG Boundary-Scan Timing...........................................................................6-46
6-33 Intel® Quick Capture Interface Timing .............................................................6-47
6-34 MultiMedia Card timing Diagrams ....................................................................6-48
6-35 SD/SDIO timing diagrams ................................................................................6-49
Tables
1-1 Supplemental Documentation ............................................................................1-2
3-1 Processor Material Properties ............................................................................3-7
4-1 Pin Use Summary ............................................................................................4-10
4-2 Pin Use and Mapping Notes.............................................................................4-27
4-3 Signal Types.....................................................................................................4-28
4-4 Memory Controller Pin Reset Values ...............................................................4-28
4-5 Discrete (13x13 VF-BGA) Power Supply Pin Summary...................................4-29
5-1 Absolute Maximum Ratings................................................................................5-1
5-2 Voltage, Temperature, and Frequency Electrical Specifications........................5-2
5-3 Memory Voltage and Frequency Electrical Specifications .................................5-4
5-4 Core Voltage and Frequency Electrical Specifications.......................................5-4
5-5 Internally Generated Power Domain Descriptions .............................................5-6
5-6 Core Voltage Specifications For Lower Power Modes .......................................5-6
5-7 Typical Power-Consumption Specifications .......................................................5-7
5-8 Maximum Idle and Low Power Mode Power-Consumption Specifications ........5-8
5-9 Standard Input, Output, and I/O Pin DC Operating Conditions ..........................5-9
5-10 Typical 32.768-kHz Crystal Requirements .......................................................5-11
5-11 Typical External 32.768-kHz Oscillator Requirements ....................................5-12
5-12 Typical 13.000-MHz Crystal Requirements......................................................5-12
Electrical, Mechanical, and Thermal Specification
v
Intel® PXA270 Processor
Contents
5-13Typical External 13.000-MHz Oscillator Requirements....................................5-13
5-14CLK_PIO Specifications...................................................................................5-13
5-15CLK_TOUT Specifications ...............................................................................5-13
5-1648 MHz Output Specifications..........................................................................5-14
6-1 Standard Input, Output, and I/O-Pin AC Operating Conditions..........................6-1
6-2 Power-On Timing Specifications(OSCC[CRI] = 0) .............................................6-3
6-3 Hardware Reset Timing Specifications (OSCC[CRI] = 0) ..................................6-4
6-4 Hardware Reset Timing Specifications (OSCC[CRI] = 1) .................................6-4
6-5 GPIO Reset Timing Specifications ..................................... 6-5
6-6 Sleep-Mode Timing Specifications.....................................................................6-6
6-7 Deep-Sleep Mode Timing Specifications ...........................................................6-7
6-8 GPIO Pu/Pd Timing Specifications for Deep-Sleep Mode .................................6-8
6-9 Standby-Mode Timing Specifications .................................................................6-9
6-10Idle-Mode Timing Specifications ........................................................................6-9
6-11Frequency-Change Timing Specifications .........................................................6-9
6-12Voltage-Change Timing Specification for a 1-Byte Command .........................6-10
6-13GPIO Timing Specifications .............................................................................6-10
6-14SRAM Read/Write AC Specification ................................................................6-11
6-15SDRAM Interface AC Specifications ................................................................6-12
6-16ROM AC Specification .....................................................................................6-17
6-17Synchronous Flash Read AC Specifications....................................................6-23
6-18Flash Memory AC Specification .......................................................................6-29
6-19SRAM Write AC Specification ..........................................................................6-33
6-20VLIO Timing .....................................................................................................6-36
6-21Expansion-Card Interface AC Specifications ...................................................6-39
6-22LCD Timing Specifications ...............................................................................6-42
6-23SSP Master Mode Timing Specifications .........................................................6-44
6-24Timing Specification SSP Slave Mode Transmitting Data to External
Peripheral.........................................................................................................6-45
6-25Timing Specification for SSP Slave Mode Receiving Data from External
Peripheral.........................................................................................................6-45
6-26Boundary Scan Timing Specifications..............................................................6-45
6-27Intel® Quick Capture AC Timing Specification.................................................6-47
6-28MultiMedia Card timing specifications ..............................................................6-48
6-29SD/SDIO Timing Specifications .......................................................................6-49
vi
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Contents
Revision History
Date
Revision
April 2004
-001
First public release of the EMTS
June 2004
-002
Added 23x23 mm 360-ball PBGA package
June 2004
-003
Added 624-MHz active and idle power consumption values to
Table 5-7.
Electrical, Mechanical, and Thermal Specification
Description
vii
Intel® PXA270 Processor
Contents
Date
Revision
Description
Modified Power Consumption introduction in Chapter 5, “PowerConsumption Specifications”
October 2004
-004
Modified Watchdog Reset timing description Chapter 6,
“Watchdog Reset Timing”
Corrected 13 MHz Oscillator slew rate specification Section 5.5,
“Oscillator Electrical Specifications”
Added note to VCC_BB voltage specifications, Chapter 5,
“Electrical Specifications”
April 2005
-005
Modified Core Voltage and Frequency Electrial Specifications,
Chapter 5, “Electrical Specifications”
Modified SDRAM Parameters and Timing Diagrams, Chapter 6,
“AC Timing Specifications”
Modified Processor Material Properties,Chapter 3, “Package
Information”
Updates made based on “July 2006 Intel® PXA27x Processor
Family Specification Update”
Extended Input DC operating conditions for USB interfaces,
Chapter 5, “Standard Input, Output, and I/O Pin DC Operating
Conditions”
32.768-kHz crystal load capacitance specification updated,
Chapter 5, “Typical 32.768-kHz Crystal Requirements”
SDRAM 3.3V Interface AC Timing Specification updated,
Chapter 6, “SDRAM Interface AC Specifications”
Synchronous Flash AC Timing Specification updated, Chapter
6, “Synchronous Flash Read AC Specifications”
Intel® Quick Capture Interface AC Timing added, Chapter 6,
“Intel® Quick Capture AC Timing Specification”
SDRAM Timing Parameter tsdCL Description Correction,
Chapter 6, “SDRAM Interface AC Specifications”
VLIO Timing Parameter tvlioDH Correction, Chapter 6, “VLIO
Timing”
August 2006
-006
Derating Specifications Are Removed From EMTS, Chapter 6,
“Standard Input, Output, and I/O-Pin AC Operating Conditions”
23x23 package ball diameter infomation update inChapter 3,
“23x23 mm PBGA Intel® PXA270 Processor Package (Bottom
View)”
MMC/SD/SDIO timings added to Chapter 6, “MultiMedia Card
timing Diagrams”, Chapter 6, “SD/SDIO timing diagrams”
Maximum low power mode power consumption added to
Chapter 5, “Maximum Idle and Low Power Mode PowerConsumption Specifications”
32.768-kHz crystal equivalent series resistance correction.
Chapter 5, “Typical 32.768-kHz Crystal Requirements”
LCD controller timing specification updated, Chapter 6, “LCD
Timing Specifications”
GPIO reset nRESET_OUT and GPIO<1> pulse width
correction. Chapter 6, “GPIO Reset Timing”
nBATT_FAULT and nRESET power-on reset description
correction. Chapter 6, “Power-On Timing Specifications”
ROM timing parameters tromAVDVF and tromAVDVS
correction. Chapter 6, “ROM AC Specification”
§§
viii
Electrical, Mechanical, and Thermal Specification
Introduction
1
The Intel® PXA270 processor (PXA270 processor) provides industry-leading multimedia
performance, low-power capabilities, rich peripheral integration and second generation memory
stacking. Designed from the ground up for wireless clients, it incorporates the latest Intel advances
in mobile technology over its predecessor, the Intel® PXA255 processor. These same attributes
and features also make the PXA270 processor ideal for embedded applications. The PXA270
processor redefines scalability by operating from 104 MHz up to 624 MHz, providing enough
performance for the most demanding mobile applications.
The PXA270 processor is the first Intel processor to include Intel® Wireless MMX™ technology,
enabling high-performance, low-power multimedia acceleration with a general-purpose instruction
set. Intel® Quick Capture technology provides a flexible and powerful camera interface for
capturing digital images and video. While performance is key in the PXA270 processor, power
consumption is also a critical component. The new capabilities of Wireless Intel SpeedStep®
technology set the standard for low-power consumption.
The PXA270 processor is offered in two packages: 13x13 mm VFBGA and 23x23 mm PBGA.
1.1
About This Document
This document constitutes the electrical, mechanical, and thermal specifications for the PXA270
processor. It contains a functional overview, mechanical data, package signal locations, targeted
electrical specifications, and functional bus waveforms. For detailed functional descriptions other
than parametric performance, refer to the Intel® PXA27x Processor Family Developers Manual.
1.1.1
Number Representation
All numbers in this document are base 10 unless designated otherwise. Hexadecimal numbers have
a prefix of 0x, and binary numbers have a prefix of 0b. For example, 107 is represented as 0x6B in
hexadecimal and 0b110_1011 in binary.
1.1.2
Typographical Conventions
All signal and register-bit names appear in uppercase. Active low items are prefixed with a
lowercase “n”.
Bits within a signal name are enclosed in angle brackets:
EXTERNAL_ADDRESS<31:0>
nCS<1>
Bits within a register bit field are enclosed in square brackets:
REGISTER_BITFIELD[3:0]
REGISTER_BIT[0]
Electrical, Mechanical, and Thermal Specification
1-1
Intel® PXA270 Processor
Introduction
Single-bit items have either of two states:
• clear — the item contains the value 0b0. To clear a bit, write 0b0 to it.
• set — the item contains the value 0b1. To set a bit, write 0b1 to it.
1.1.3
Applicable Documents
Table 1-1 lists supplemental information sources for the PXA270 processor. Contact an Intel
representative for the latest document revisions and ordering instructions.
Table 1-1. Supplemental Documentation
Document Title
Intel® PXA27x Processor Family Developers Manual
ARM® Architecture Version 5T Specification (Document number ARM* DDI 0100D-10), and ARM®
Architecture Reference Manual (Document number ARM* DDI 0100B)
Intel® XScale™ Core Developer’s Manual
Intel® Wireless MMX™ Technology Developer’s Guide
Intel® PXA27x Processor Design Guide
Intel® PXA27x Processor Power Supply Requirements Application Note
§§
1-2
Electrical, Mechanical, and Thermal Specification
Functional Overview
2
The Intel® PXA270 processor is an integrated system-on-a-chip microprocessor for high
performance, dynamic, low-power portable handheld and hand-set devices as well as embedded
platforms. It incorporates the Intel XScale® technology which complies with the ARM* version
5TE instruction set (excluding floating-point instructions) and follows the ARM* programmer’s
model. The PXA270 processor also provides Intel® Wireless MMX™ media enhancement
technology, which supports integer instructions to accelerate audio and video processing. In
addition, it incorporates Wireless Intel Speedstep® Technology, which provides sophisticated
power management capabilities enabling excellent MIPs/mW performance.
The PXA270 processor provides a scalable, bi-directional data interface to a cellular baseband
processor, supporting seven logical channels and other features. The operating-system (OS) timer
channels and synchronous serial ports (SSPs) also accept an external network clock input so that
they can be synchronized to the cellular network. The processor also provides a Universal
Subscriber Identity Module* (USIM) card interface.
The PXA270 processor memory interface gives designers flexibility as it supports a variety of
external memory types. The processor also provides four 64 kilobyte banks of on-chip SRAM,
which can be used for program code or multimedia data. Each bank can be configured
independently to retain its contents when the processor enters a low-power mode. An integrated
LCD panel controller supports displays up to 800 by 600 pixels, permitting 1-, 2-, 4-, and 8-bit gray
scale and 1-, 2-, 4-, 8-, 16-, 18-, and 24-bit color pixels. A 256-byte palette RAM provides flexible
color mapping.
A set of serial devices and general-system resources offers computational and connectivity
capability for a variety of applications. Figure 2-1 shows the block diagram for a typical PXA270
processor system.
Electrical, Mechanical, and Thermal Specification
2-1
Intel® PXA270 Processor
Functional Overview
Figure 2-1. Intel® PXA270 Processor Block Diagram, Typical System
LCD
LCD
RTC
RTC
44xxPWM
PWM
Memory
Memory
Controller
Controller
Interrupt
Interrupt
Controller
C ontrolle r
InternalInternal LCDLCD
Camera
Controller
SRAM SRAM
Controller
Interface
33xxSSP
SSP
USIM
U SIM
Full
FullFunction
Func tion
UART
UA RT
Bluetooth
Bluet oot h*
UART
UAR T
IrDA
IrD A
22
I ICC
USB
U SB
Client
Client
BB
Processor
B B Pr ocess or
Interface
Inter face
Keypad
Ke ypad
Interface
Interfa ce
SDCard/MMC
S DC ard/M MC
Interface
Inter face
Memory
MemoryStick
Stick
Interface
Int er face
USB
USB
OTG
OTG
Camera
Interface
Variable
Variable
Latency
Latency I/O
I/O
Control
Control
DMA
DMA
Controller
Controller
And
and
Bridge
Bridge
System
System Bus
Bus
Intel®Wireless
WirelessMMX™
MMX™
Intel®
GeneralPur
Purpose
I/O
General
pose I/O
AC97
AC 97
Peripheral
Bus
Per
iphera l Bus
2
I2IS
S
Address
Address
and
and
Data
Data
Intel®
Intel®
®
XScale™
XScale™
USB
USB
Host
Host
Debug
Debug
Controller
Controller
13
13
MHz
MHz
Osc
Osc
Power
PowerManagement
Management
Clock
ClockControl
Control
ASIC
ASIC
Socket
Socket00
PCMCIA
PCMCIA &&CF
CF
Control
Control
MicroMicroarchitecture
architecture
Addressand
andData
DataBBus
Address
us
OS
OSTimers
Tim ers
32.768
32.768
kHz
kHz
Osc
Osc
Dynamic
Dynamic
Memory
Memor y
Control
Control
Static
Static
Memory
Memory
Control
Control
XCVR
XCVR Socket
Socket11
SDRAM/
SDRAM
Boot
ROM
ROM/
ROM/
Flash/
Flash/
SRAM
SRAM
Primary
Primar yGPIO
GPIO
JTAG
JTAG
§§
2-2
Electrical, Mechanical, and Thermal Specification
Package Information
3
This chapter provides the mechanical specifications for the PXA270 processor.
The PXA270 processor is offered in two packages. The 13- by 13-mm, 356-ball, 0.50-mm VFBGA molded matrix array package is shown in Figure 3-1, Figure 3-2, and Figure 3-3. The 23- by
23-mm, 360-ball, 1.0-mm PBGA molded matrix array package is shown in Figure 3-5, Figure 3-6,
and Figure 3-7.
3.1
Package Information
Figure 3-1. 13x13mm VF-BGA Intel® PXA270 Processor Package, top view
A1 Corner
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Y
AA
AB
AC
AD
Electrical, Mechanical, and Thermal Specification
3-1
Intel® PXA270 Processor
Package Information
Note:
Figure 3-2 and Figure 3-3 show all dimensions in millimeters (mm).
Figure 3-2. 13x13mm VF-BGA Intel® PXA270 Processor Package, bottom view
0.15 M C
0.15 M C A B
0.50
11.50
13±0.10
ø0.30±0.05 (356)
0.50
A
11.50
B
3-2
13±0.10
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Package Information
0.18 MIN. – 0.30 MAX.
C
0.91 MIN. - 1.0 MAX.
0.12 C
0.10 C
SEATING PLANE
0.21±0.04
0.45±0.05
Figure 3-3. 13x13mm VF-BGA Intel® PXA270 Processor Package, side view
Figure 3-4. VF-BGA Product Information Decoder
R
C
P
X
Package Type
RC=Leaded
RT=Lead-Free
Intel XScale® Family
Product Family Member
270=Discrete product
Electrical, Mechanical, and Thermal Specification
A
2
7
0
C
0
C
4
1
6
Speed
312 MHz
416 MHz
520 MHz
624 MHz
Commercial
Temperature rating
Stepping
3-3
Intel® PXA270 Processor
Package Information
Note:
Figure 3-5, Figure 3-6 and Figure 3-7 show all dimensions in millimeters (mm).
Figure 3-5. 23x23 mm PBGA Intel® PXA270 Processor Package (Top View)
A1 CORNER
14.70 ± 0.25
Figure 3-6. 23x23 mm PBGA Intel® PXA270 Processor Package (Bottom View)
PIN #1
CORNER
22 20 18 16 14 12 10 8 6 4 2
21 19 17 15 13 11 9 7 5 3 1
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Y
AA
AB
1.00
1.00
Ball Diameter = 0.60 +/-0.10 mm
1.00
3-4
1.00
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Package Information
Figure 3-7. 23x23 mm PBGA Intel® PXA270 Processor Package (Side View)
//
0.15 C
0.20 C
3
SEATING PLANE
Figure 3-8. PBGA Product Information Decoder
F
W
P
X
Package Type
FW = Leaded
NH = Lead-Free
Intel XScale® Family
Product Family Member
270 = Discrete product
Electrical, Mechanical, and Thermal Specification
A
2
7
0
C
1
C
4
1
6
Speed
312 MHz
416 MHz
520 MHz
Temperature Rating
C = -25 to 85 C
E = -40 to 85 C
Stepping
3-5
Intel® PXA270 Processor
Package Information
3.2
Processor Materials
Figure 3-9. 13x13mm VF-BGA Intel® PXA270 Processor Package, bottom view
Table 3-1 describes the basic material properties of the processor components.
3-6
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Package Information
Table 3-1. Processor Material Properties
3.3
3.4
Component
VF-BGA Material
PBGA Material
Mold compound
ShinEtsu KMC 2500 VAT1
Sumitomo G770LE
Solder balls(Leaded)
63% Sn/37% Pb
63% Sn/37% Pb
Solder balls(Pb-free)
94.5% Sn / 5.0% Ag / 0.5% Cu
94.5% Sn / 5.0% Ag / 0.5% Cu
Junction To Case Temperature Thermal Resistance
Parameter
VF-BGA Value and Units
PBGA Value and Units
Theta Jc
2 degrees C / watt
1.4 degrees C / watt
Processor Markings
The diagram in this section details the processor’s top markings, which identify the PXA270
processor in the 356-ball VF-BGA and 360-ball PBGA package. Refer to Figure 3-4 for product
information. A Pb-Free (lead-free) package is indicated by the letter “E” on the 3rd line of
information (Intel legal line). The “E” appears after the date stamp.
Figure 3-10. Intel® PXA270 Processor Production Markings, (Laser Mark on Top Side)
Laser Mark on top side of Package
i
Product
PXA270C0C416
FPO#
Lot #
M C ‘03
Intel Legal
TAIWAN
COO
PIN 1 INDICATOR
Electrical, Mechanical, and Thermal Specification
3-7
Intel® PXA270 Processor
Package Information
3.5
Tray Drawing
For tray drawing information, refer to the Intel Developer website for the Intel® Wireless
Communications and Computing Package Users Guide.
§§
3-8
Electrical, Mechanical, and Thermal Specification
Pin Listing and Signal Definitions
4
This chapter describes the signals and pins for the Intel® PXA270 processor.
For descriptions of all PXA270 processor signals, refer to the “System Architecture” chapter in the
Intel® PXA27x Processor Family Developer’s Manual.
Table 4-2 lists the mapping of signals to specific package pins. Many of the package pins are
multiplexed so that they can be configured for use as a general-purpose I/O signal or as one of two
or three alternate functions using the GPIO alternate-function select registers. Some signals can be
configured to appear on one of several different package pins.
Electrical, Mechanical, and Thermal Specification
4-1
Intel® PXA270 Processor
Pin Listing and Signal Definitions
4.1
Ball Map View
Note:
4.1.1
In the following ball map figures the lowercase letter “n”, which normally indicates negation,
appears as uppercase “N”.
13x13 mm VF-BGA Ball map
Figure 4-1 through Figure 4-4 shows the ball map for the VF-BGA PXA270 processor.
Figure 4-1. 13x13 mm VF-BGA Ball Map, Top View (upper left quarter)
1
4-2
2
3
4
5
6
VCC_MEM
VCC_SRAM
MA<1>
A
VSS_CORE VSS_CORE
GPIO<15>
B
VSS_CORE VSS_CORE
NCS<0>
VCC_SRAM VSS_CORE
7
8
9
VCC_CORE VCC_SRAM VCC_SRAM
10
11
12
GPIO<49>
GPIO<47>
VCC_IO
GPIO<33>
GPIO<78>
VCC_MEM
GPIO<18>
GPIO<12>
GPIO<46>
VCC_CORE
GPIO<80>
GPIO<79>
RDNWR
GPIO<13>
GPIO<11>
GPIO<31>
VSS_MEM
VSS_CORE
VSS_IO
VSS_CORE
C
MA<18>
MA<22>
VCC_MEM
MA<24>
VSS_MEM
MA<0>
D
MA<17>
MA<21>
VCC_CORE
MA<23>
VSS_MEM
MA<25>
E
MA<13>
VCC_MEM
MA<19>
MA<20>
F
VCC_MEM
MA<14>
MA<16>
VSS_MEM
G
MA<8>
MA<11>
MA<12>
MA<15>
H
VCC_MEM
MA<9>
MA<10>
VSS_MEM
J
MA<3>
MA<6>
MA<7>
VSS_MEM
K
MD<15>
MA<4>
MA<5>
MA<2>
VSS_CORE VSS_CORE VSS_CORE
L
MD<14>
MD<31>
VCC_MEM
VSS_MEM
VSS_CORE VSS_CORE VSS_CORE
M
VCC_MEM
MD<30>
MD<29>
MD<13>
VSS_CORE VSS_CORE VSS_CORE
VSS_CORE VSS_CORE
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Figure 4-2. 13x13 mm VF-BGA Ball Map, Top View (upper right quarter)
13
14
15
16
17
18
19
20
21
22
23
24
GPIO<113>
GPIO<28>
GPIO<37>
VCC_IO
GPIO<24>
GPIO<16>
GPIO<92>
GPIO<32>
GPIO<34>
GPIO<118>
VCC_USB
VCC_USB
A
GPIO<29>
GPIO<38>
GPIO<26>
GPIO<23>
GPIO<110> GPIO<112>
GPIO<35>
GPIO<44>
VCC_CORE
USBC_P
VCC_USB
VCC_USB
B
GPIO<30>
GPIO<36>
GPIO<27>
GPIO<17>
GPIO<111>
GPIO<41>
GPIO<45>
USBC_N
GPIO<42>
GPIO<43>
GPIO<88>
GPIO<116>
C
GPIO<22>
GPIO<40>
VSS_IO
GPIO<25>
GPIO<109>
VSS_IO
GPIO<39>
USBH_N<1> GPIO<114>
D
GPIO<117> VSS_CORE
GPIO<89>
GPIO<115> USBH_P<1>
UIO
VCC_USIM
E
VSS_IO
GPIO<90>
GPIO<91>
VCC_CORE
F
VSS_CORE
GPIO<59>
GPIO<60>
GPIO<58>
G
VSS_IO
GPIO<62>
GPIO<63>
GPIO<61>
H
VSS_CORE
GPIO<64>
VCC_CORE
VCC_LCD
J
VSS_CORE VSS_CORE VSS_CORE
VSS_CORE
GPIO<66>
GPIO<67>
GPIO<65>
K
VSS_CORE VSS_CORE VSS_CORE
GPIO<68>
GPIO<71>
GPIO<69>
VCC_CORE
L
VSS_CORE VSS_CORE VSS_CORE
VSS_CORE
GPIO<73>
VCC_CORE
GPIO<70>
M
Electrical, Mechanical, and Thermal Specification
4-3
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Figure 4-3. 13x13 mm VF-BGA Ball Map, Top View (bottom left quarter)
4-4
N
MD<27>
MD<28>
MD<12>
VSS_MEM
VSS_CORE VSS_CORE VSS_CORE
P
VCC_MEM
MD<11>
MD<26>
MD<10>
VSS_CORE VSS_CORE VSS_CORE
R
MD<24>
VSS_MEM
MD<25>
MD<9>
VSS_CORE VSS_CORE VSS_CORE
T
MD<23>
VCC_CORE
MD<8>
VSS_MEM
U
MD<7>
VCC_MEM
VSS_CORE
MD<5>
V
MD<21>
MD<22>
MD<6>
VSS_MEM
W
MD<20>
VCC_MEM
Y
MD<19>
MD<4>
MD<3>
VSS_MEM
AA
MD<18>
VCC_MEM
MD<2>
MD<16>
VSS_MEM
NSDCAS
VSS_CORE
VSS_MEM
VSS_MEM
GPIO<55>
GPIO<84>
VSS_CORE
AB
MD<1>
VSS_MEM
MD<17>
MD<0>
NWE
GPIO<20>
NSDCS<0>
NSDCS<1>
DQM<0>
DQM<1>
GPIO<56>
GPIO<81>
AC
VCC_MEM
VCC_MEM
VSS_MEM
SDCLK<0>
NOE
VCC_MEM
NSDRAS
VCC_MEM
DQM<2>
DQM<3>
GPIO<57>
GPIO<85>
AD
VCC_MEM
VCC_MEM
SDCLK<2> VCC_CORE
GPIO<21>
SDCKE
SDCLK<1>
VCC_MEM
GPIO<82>
GPIO<83>
VCC_CORE
VCC_BB
1
2
5
6
7
8
9
10
11
12
VCC_CORE VSS_CORE
3
4
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Figure 4-4. 13x13 mm VF-BGA Ball Map, Top View (bottom right quarter)
VSS_CORE VSS_CORE VSS_CORE
VSS_IO
GPIO<86>
GPIO<87>
GPIO<72>
N
VSS_CORE VSS_CORE VSS_CORE
VSS_CORE
GPIO<76>
GPIO<75>
VCC_LCD
P
VSS_CORE VSS_CORE VSS_CORE
GPIO<77>
GPIO<19>
GPIO<74>
VCC_CORE
R
TMS
TCK
TESTCLK
GPIO<14>
T
NTRST
GPIO<9>
TDI
VSS_IO
U
VSS
GPIO<0>
GPIO<10>
TDO
V
GPIO<3>
NVDD_FAUL
T
GPIO<4>
CLK_REQ
W
NRESET_O
UT
NRESET
PWR_EN
GPIO<1>
Y
VSS
TXTAL_IN
TXTAL_OUT
SYS_EN
AA
PWR_CAP<
PWR_OUT
0>
BOOT_SEL
NBATT_FAU
LT
AB
VSS_BB
GPIO<54>
VSS_CORE
GPIO<97>
GPIO<95>
VSS_IO
PWR_CAP<
3>
GPIO<50>
GPIO<53>
GPIO<106> GPIO<105> GPIO<102>
GPIO<99>
GPIO<93>
VCC_BATT
GPIO<48>
GPIO<52>
GPIO<107> GPIO<103> GPIO<101> GPIO<100>
GPIO<96>
VCC_PLL
PXTAL_IN
PWR_CAP<
2>
VSS
VSS
AC
GPIO<51>
GPIO<108> GPIO<104> VCC_CORE
AD
13
14
15
VSS_IO
16
VCC_IO
GPIO<98>
GPIO<94>
VSS_PLL
PXTAL_OUT
PWR_CAP<
1>
VSS
VSS
17
18
19
20
21
22
23
24
Electrical, Mechanical, and Thermal Specification
4-5
Intel® PXA270 Processor
Pin Listing and Signal Definitions
4.1.2
23x23 mm PBGA Ball map
Figure 4-5. 23x23 mm PBGA Ball Map, Top View (Upper Left Quarter)
4-6
1
2
3
4
5
6
7
8
9
10
11
A
VSS_MEM
VSS_MEM
MA[25]
GPIO[15]
GPIO[79]
GPIO[13]
GPIO[12]
GPIO[11]
GPIO[46]
GPIO[113]
GPIO[29]
B
VSS_MEM
VCC_MEM
VSS_MEM
VCC_RAM
MA[1]
VSS_MEM
VCC_RAM
VCC_RAM
VSS_MEM
VCC_IO
GPIO[30]
C
MA[16]
MA[17]
VCC_MEM
MA[24]
VCC_RAM
VCC_MEM
GPIO[33]
RDNWR
VCC_MEM
GPIO[47]
GPIO[31]
D
MA[14]
MA[15]
MA[19]
MA[22]
MA[0]
NCS_0
GPIO[80]
GPIO[78]
GPIO[18]
GPIO[49]
VCC_CORE
E
MA[11]
MA[12]
MA[21]
MA[23]
VSS_CORE VCC_CORE VSS_CORE VCC_CORE VSS_CORE
F
MA[9]
VSS_MEM
VCC_MEM
MA[20]
VCC_CORE
G
MA[7]
MA[8]
MA[13]
MA[18]
VSS_CORE
H
MA[4]
VSS_MEM
VCC_MEM
MA[10]
VCC_CORE
J
MA[3]
MA[2]
MA[6]
MA[5]
VSS_CORE
K
MD[15]
MD[30]
VCC_MEM
MD[31]
VSS_CORE VSS_CORE VSS_CORE
L
MD[14]
VSS_MEM
MD[29]
VCC_CORE
VSS_CORE VSS_CORE VSS_CORE
VSS_CORE VSS_CORE VSS_CORE
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Figure 4-6. 23x23 mm PBGA Ball Map, Top View (Upper Right Quarter)
12
13
14
15
16
17
18
19
20
21
22
GPIO[22]
GPIO[38]
GPIO[26]
GPIO[25]
GPIO[23]
GPIO[111]
GPIO[92]
GPIO[41]
GPIO[44]
VCC_USB
VCC_USB
A
VSS_IO
GPIO[36]
GPIO[24]
VSS_IO
GPIO[112]
GPIO[39]
VSS_IO
GPIO[34]
GPIO[118]
GPIO[43]
VCC_USB
B
GPIO[40]
GPIO[27]
GPIO[16]
GPIO[110]
GPIO[32]
GPIO[45]
GPIO[117]
NC
NC
GPIO[89]
GPIO[88]
C
GPIO[28]
GPIO[37]
VCC_IO
GPIO[17]
GPIO[109]
GPIO[35]
USBC_P
VCC_USB
GPIO[42]
VSS_IO
USBH_N[1]
D
USBC_N
GPIO[116]
GPIO[115]
USBH_P[1]
E
VCC_CORE
GPIO[114]
UIO
VCC_USIM
GPIO[61]
F
VSS_CORE
GPIO[91]
GPIO[58]
GPIO[60]
GPIO[62]
G
VCC_CORE
GPIO[90]
GPIO[59]
VSS_IO
GPIO[64]
H
VSS_CORE
GPIO[66]
GPIO[63]
VCC_LCD
GPIO[69]
J
VSS_CORE VSS_CORE VSS_CORE
GPIO[67]
GPIO[65]
GPIO[68]
GPIO[70]
K
VSS_CORE VSS_CORE VSS_CORE
VCC_CORE
GPIO[71]
GPIO[72]
GPIO[73]
L
VSS_CORE VCC_CORE VSS_CORE VCC_CORE VSS_CORE
VSS_CORE VSS_CORE VSS_CORE
Electrical, Mechanical, and Thermal Specification
4-7
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Figure 4-7. 23x23 mm PBGA Ball Map, Top View (Lower Left Quarter)
4-8
M
MD[13]
MD[11]
VCC_MEM
MD[12]
VSS_CORE VSS_CORE VSS_CORE
N
MD[28]
MD[26]
MD[24]
MD[25]
VSS_CORE VSS_CORE VSS_CORE
P
MD[27]
VSS_MEM
VCC_MEM
MD[8]
VSS_CORE
R
MD[10]
MD[23]
MD[21]
MD[7]
VCC_CORE
T
MD[9]
VSS_MEM
VCC_MEM
MD[5]
VSS_CORE
U
MD[22]
MD[6]
MD[4]
MD[2]
VCC_CORE
V
MD[20]
VSS_MEM
VCC_MEM
MD[16]
VSS_CORE VCC_CORE VSS_CORE VCC_CORE VSS_CORE
W
MD[19]
MD[18]
MD[1]
MD[0]
GPIO[20]
NSDRAS
SDCKE
DQM[0]
GPIO[55]
GPIO[81]
VCC_CORE
Y
MD[3]
MD[17]
VCC_MEM
NSDCAS
VCC_MEM
GPIO[21]
VCC_MEM
NSDCS[1]
VCC_MEM
GPIO[84]
GPIO[48]
AA
VSS_MEM
VCC_MEM
NWE
NOE
NSDCS[0]
VSS_MEM
DQM[1]
GPIO[82]
VSS_MEM
GPIO[85]
VCC_BB
AB
VSS_MEM
VSS_MEM
SDCLK[0]
SDCLK[2]
SDCLK[1]
DQM[2]
DQM[3]
GPIO[56]
GPIO[57]
GPIO[83]
VSS_BB
1
2
3
4
5
6
7
8
9
10
11
VSS_CORE VSS_CORE VSS_CORE
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Figure 4-8. 23x23 mm PBGA Ball Map, Top View (Lower Right Quarter)
VSS_CORE VSS_CORE VSS_CORE
VCC_LCD
GPIO[86]
VSS_IO
GPIO[87]
M
VSS_CORE VSS_CORE VSS_CORE
VSS_IO
GPIO[75]
GPIO[76]
GPIO[74]
N
VSS_CORE
GPIO[19]
GPIO[14]
GPIO[77]
TESTCLK
P
VCC_CORE
TCK
TMS
TDO
TDI
R
VSS_CORE
GPIO[4]
NTRST
CLK_REQ
GPIO[9]
T
VCC_CORE
NBATT_FAU
LT
GPIO[0]
GPIO[1]
GPIO[10]
U
NVDD_FAUL
T
SYS_EN
GPIO[3]
V
VSS_CORE VSS_CORE VSS_CORE
VSS_CORE VCC_CORE VSS_CORE VCC_CORE VSS_CORE BOOT_SEL
4.2
GPIO[50]
GPIO[106]
GPIO[104]
VCC_IO
GPIO[96]
PWR_CAP
[3]
VSS
PWR_OUT
NRESET
NRESET_O
UT
PWR_EN
W
GPIO[52]
GPIO[105]
GPIO[102]
GPIO[97]
GPIO[93]
VCC_BATT
PWR_CAP
[2]
PWR_CAP
[0]
VSS
TXTAL_IN
TXTAL_OUT
Y
GPIO[53]
GPIO[108]
VSS_IO
GPIO[100]
GPIO[98]
GPIO[94]
VSS_IO
VSS_PLL
PXTAL_OUT
PWR_CAP
[1]
VSS
AA
GPIO[51]
GPIO[54]
GPIO[107]
GPIO[103]
GPIO[101]
GPIO[99]
GPIO[95]
VCC_PLL
PXTAL_IN
VSS
VSS
AB
12
13
14
15
16
17
18
19
20
21
22
Pin Use
The pin-use summary shown in Table 4-1 does not include the 36 center balls identified as K10
through R15 (VF-BGA) or J9 through P14 (PBGA), all of which function as VSS_CORE (see the
recommendations for connecting the 36 center balls in the Intel® PXA27x Processor Family
Design Guide).
Each signal’s alternate function inputs are shown in the upper section of each signal row and the
outputs are shown in the lower section of each signal row. For example, GPIO<48> has a primary
input function of CIF_DD<5> and a secondary output function of nPOE.
Electrical, Mechanical, and Thermal Specification
4-9
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Table 4-1. Pin Use Summary (Sheet 1 of 17)
VF-BGA
Ball#
(13x13)
PBGA
Ball#
(23x23)
Name
Type
Function
After
Reset
Primary
Function
Secondary
Alternate
Function
Third
Alternate
Function
D6
A3
MA<25>
OCZ
MA<25>
MA<25>
—
—
C4
C4
MA<24>
OCZ
MA<24>
MA<24>
—
—
Refer to Table 4-4
D4
E4
MA<23>
OCZ
MA<23>
MA<23>
—
—
Refer to Table 4-4
C2
D4
MA<22>
OCZ
MA<22>
MA<22>
—
—
Refer to Table 4-4
D2
E3
MA<21>
OCZ
MA<21>
MA<21>
—
—
Refer to Table 4-4
E4
F4
MA<20>
OCZ
MA<20>
MA<20>
—
—
Refer to Table 4-4
E3
D3
MA<19>
OCZ
MA<19>
MA<19>
—
—
Refer to Table 4-4
C1
G4
MA<18>
OCZ
MA<18>
MA<18>
—
—
Refer to Table 4-4
D1
C2
MA<17>
OCZ
MA<17>
MA<17>
—
—
Refer to Table 4-4
Reset
State
Sleep
State
VCC_MEM
Refer to Table 4-4
F3
C1
MA<16>
OCZ
MA<16>
MA<16>
—
—
Refer to Table 4-4
G4
D2
MA<15>
OCZ
MA<15>
MA<15>
—
—
Refer to Table 4-4
F2
D1
MA<14>
OCZ
MA<14>
MA<14>
—
—
Refer to Table 4-4
E1
G3
MA<13>
OCZ
MA<13>
MA<13>
—
—
Refer to Table 4-4
G3
E2
MA<12>
OCZ
MA<12>
MA<12>
—
—
Refer to Table 4-4
G2
E1
MA<11>
OCZ
MA<11>
MA<11>
—
—
Refer to Table 4-4
H3
H4
MA<10>
OCZ
MA<10>
MA<10>
—
—
Refer to Table 4-4
H2
F1
MA<9>
OCZ
MA<9>
MA<9>
—
—
Refer to Table 4-4
G1
G2
MA<8>
OCZ
MA<8>
MA<8>
—
—
Refer to Table 4-4
J3
G1
MA<7>
OCZ
MA<7>
MA<7>
—
—
Refer to Table 4-4
J2
J3
MA<6>
OCZ
MA<6>
MA<6>
—
—
Refer to Table 4-4
K3
J4
MA<5>
OCZ
MA<5>
MA<5>
—
—
Refer to Table 4-4
K2
H1
MA<4>
OCZ
MA<4>
MA<4>
—
—
Refer to Table 4-4
J1
J1
MA<3>
OCZ
MA<3>
MA<3>
—
—
Refer to Table 4-4
K4
J2
MA<2>
OCZ
MA<2>
MA<2>
—
—
Refer to Table 4-4
A6
B5
MA<1>
OCZ
MA<1>
MA<1>
—
—
Refer to Table 4-4
C6
D5
MA<0>
OCZ
MA<0>
MA<0>
—
—
Refer to Table 4-4
MD<31>
MD<31>
—
—
Refer to Table 4-4
L2
K4
MD<31>
ICOC
Z
M2
K2
MD<30>
ICOC
Z
MD<30>
MD<30>
—
—
Refer to Table 4-4
M3
L3
MD<29>
ICOC
Z
MD<29>
MD<29>
—
—
Refer to Table 4-4
N2
N1
MD<28>
ICOC
Z
MD<28>
MD<28>
—
—
Refer to Table 4-4
NOTE: Refer to Table 4-2 for Numbered Notes on Reset and Sleep States.
4-10
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Table 4-1. Pin Use Summary (Sheet 2 of 17)
VF-BGA
Ball#
(13x13)
PBGA
Ball#
(23x23)
Name
Type
Function
After
Reset
Primary
Function
Secondary
Alternate
Function
Third
Alternate
Function
N1
P1
MD<27>
ICOC
Z
MD<27>
MD<27>
—
—
Refer to Table 4-4
P3
N2
MD<26>
ICOC
Z
MD<26>
MD<26>
—
—
Refer to Table 4-4
R3
N4
MD<25>
ICOC
Z
MD<25>
MD<25>
—
—
Refer to Table 4-4
R1
N3
MD<24>
ICOC
Z
MD<24>
MD<24>
—
—
Refer to Table 4-4
T1
R2
MD<23>
ICOC
Z
MD<23>
MD<23>
—
—
Refer to Table 4-4
V2
U1
MD<22>
ICOC
Z
MD<22>
MD<22>
—
—
Refer to Table 4-4
V1
R3
MD<21>
ICOC
Z
MD<21>
MD<21>
—
—
Refer to Table 4-4
W1
V1
MD<20>
ICOC
Z
MD<20>
MD<20>
—
—
Refer to Table 4-4
Y1
W1
MD<19>
ICOC
Z
MD<19>
MD<19>
—
—
Refer to Table 4-4
AA1
W2
MD<18>
ICOC
Z
MD<18>
MD<18>
—
—
Refer to Table 4-4
AB3
Y2
MD<17>
ICOC
Z
MD<17>
MD<17>
—
—
Refer to Table 4-4
AA4
V4
MD<16>
ICOC
Z
MD<16>
MD<16>
—
—
Refer to Table 4-4
K1
K1
MD<15>
ICOC
Z
MD<15>
MD<15>
—
—
Refer to Table 4-4
L1
L1
MD<14>
ICOC
Z
MD<14>
MD<14>
—
—
Refer to Table 4-4
M4
M1
MD<13>
ICOC
Z
MD<13>
MD<13>
—
—
Refer to Table 4-4
N3
M4
MD<12>
ICOC
Z
MD<12>
MD<12>
—
—
Refer to Table 4-4
P2
M2
MD<11>
ICOC
Z
MD<11>
MD<11>
—
—
Refer to Table 4-4
P4
R1
MD<10>
ICOC
Z
MD<10>
MD<10>
—
—
Refer to Table 4-4
R4
T1
MD<9>
ICOC
Z
MD<9>
MD<9>
—
—
Refer to Table 4-4
T3
P4
MD<8>
ICOC
Z
MD<8>
MD<8>
—
—
Refer to Table 4-4
U1
R4
MD<7>
ICOC
Z
MD<7>
MD<7>
—
—
Refer to Table 4-4
V3
U2
MD<6>
ICOC
Z
MD<6>
MD<6>
—
—
Refer to Table 4-4
Reset
State
Sleep
State
NOTE: Refer to Table 4-2 for Numbered Notes on Reset and Sleep States.
Electrical, Mechanical, and Thermal Specification
4-11
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Table 4-1. Pin Use Summary (Sheet 3 of 17)
VF-BGA
Ball#
(13x13)
PBGA
Ball#
(23x23)
Name
Type
Function
After
Reset
Primary
Function
Secondary
Alternate
Function
Third
Alternate
Function
U4
T4
MD<5>
ICOC
Z
MD<5>
MD<5>
—
—
Refer to Table 4-4
Y2
U3
MD<4>
ICOC
Z
MD<4>
MD<4>
—
—
Refer to Table 4-4
Y3
Y1
MD<3>
ICOC
Z
MD<3>
MD<3>
—
—
Refer to Table 4-4
AA3
U4
MD<2>
ICOC
Z
MD<2>
MD<2>
—
—
Refer to Table 4-4
AB1
W3
MD<1>
ICOC
Z
MD<1>
MD<1>
—
—
Refer to Table 4-4
AB4
W4
MD<0>
ICOC
Z
MD<0>
MD<0>
—
—
Refer to Table 4-4
AC5
AA4
NOE
OCZ
nOE
nOE
—
—
Refer to Table 4-4
AB5
AA3
NWE
OCZ
nWE
nWE
—
—
Refer to Table 4-4
AC7
W6
NSDRAS
OCZ
nSDRAS
nSDRAS
—
—
Refer to Table 4-4
AA6
Y4
NSDCAS
OCZ
nSDCAS
nSDCAS
—
—
Refer to Table 4-4
AB9
W8
DQM<0>
OCZ
DQM<0>
DQM<0>
—
—
Refer to Table 4-4
AB10
AA7
DQM<1>
OCZ
DQM<1>
DQM<1>
—
—
Refer to Table 4-4
Reset
State
Sleep
State
AC9
AB6
DQM<2>
OCZ
DQM<2>
DQM<2>
—
—
Refer to Table 4-4
AC10
AB7
DQM<3>
OCZ
DQM<3>
DQM<3>
—
—
Refer to Table 4-4
AB7
AA5
NSDCS<
0>
OCZ
nSDCS<0>
nSDCS<0>
—
—
Refer to Table 4-4
AB8
Y8
NSDCS<
1>
OC
nSDCS<1>
nSDCS<1>
—
—
Refer to Table 4-4
AD6
W7
SDCKE
OC
SDCKE
SDCKE
—
—
Refer to Table 4-4
AC4
AB3
SDCLK<0
>
OC
SDCLK<0>
SDCLK<0>
—
—
Refer to Table 4-4
AD7
AB5
SDCLK<1
>
OCZ
SDCLK<1>
SDCLK<1>
—
—
Refer to Table 4-4
AD3
AB4
SDCLK<2
>
OC
SDCLK<2>
SDCLK<2>
—
—
Refer to Table 4-4
C9
C8
RDNWR
OCZ
RDnWR
RDnWR
—
—
Refer to Table 4-4
B3
D6
NCS<0>
OCZ
nCS<0>
nCS<0>
—
—
Refer to Table 4-4
—
—
—
A3
B9
A4
D9
GPIO<15
>
ICOC
Z
GPIO<15>
GPIO<18
>
ICOC
Z
GPIO<18>
nCS<1>
nPCE<1>
Refer to
Table 4-4
—
RDY
—
—
—
—
—
Pu-1
Note[1]
Note[4]
Pd-0
Note[1]
Note [3]
NOTE: Refer to Table 4-2 for Numbered Notes on Reset and Sleep States.
4-12
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Table 4-1. Pin Use Summary (Sheet 4 of 17)
VF-BGA
Ball#
(13x13)
AB6
AD5
B6
A10
B7
C8
PBGA
Ball#
(23x23)
Name
Type
W5
GPIO<20
>
ICOC
Z
GPIO<21
>
ICOC
Z
Y6
C7
D10
D8
A5
GPIO<33
>
ICOC
Z
GPIO<49
>
ICOC
Z
GPIO<78
>
ICOC
Z
GPIO<79
>
ICOC
Z
GPIO<80
>
ICOC
Z
GPIO<48
>
ICOC
Z
Function
After
Reset
Primary
Function
Secondary
Alternate
Function
Third
Alternate
Function
DREQ<0>
MBREQ
—
Refer to
Table 4-4
—
—
—
—
—
Refer to
Table 4-4
DVAL<0>
MBGNT
FFRXD19
FFDSR19
—
nSDCS<2>
GPIO<20>
nSDCS<3>
GPIO<21>
nCS<5>
GPIO<33>
DVAL<1>
Refer to
Table 4-4
MBGNT
—
—
—
—
Refer to
Table 4-4
—
—
—
—
nPWE
GPIO<49>
nCS<2>
GPIO<78>
nPCE<2>
Refer to
Table 4-4
—
—
—
—
nCS<3>
GPIO<79>
PSKTSEL
DREQ<1>
C7
D7
Refer to
Table 4-4
MBREQ
nCS<4>
GPIO<80>
—
Refer to
Table 4-4
CIF_DD<5>
—
PWM_OUT
<2>
Reset
State
Sleep
State
Pu-1
Note[1]
Note[3]
Pu-1
Note[1]
Note[3]
Pu-1
Note[1]
Note [4]
Pu-1
Note[1]
Note [5]
Pu-1
Note[1]
Note[4]
Pu-1
Note[1]
Note[4]
Pu-1
Note[1]
Note[4]
Pu-1
Note[1]
Note [5]
Pu-1
Note[1]
Note [5]
Pu-1
Note[1]
Note [5]
—
PWM_OUT
<3>
VCC_BB
AC13
Y11
GPIO<48>
BB_OB_DAT<1
>
CIF_DD<3>
AB13
W12
GPIO<50
>
ICOC
Z
GPIO<50>
BB_OB_DAT<2
>
CIF_DD<2>
AD13
AB12
GPIO<51
>
ICOC
Z
GPIO<51>
BB_OB_DAT<3
>
—
nPOE
Refer to
Table 4-4
—
nPIOIR
Refer to
Table 4-4
—
—
SSPSCLK<
2>
SSPSCLK<
2>
—
nPIOIW
Refer to
Table 4-4
—
NOTE: Refer to Table 4-2 for Numbered Notes on Reset and Sleep States.
Electrical, Mechanical, and Thermal Specification
4-13
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Table 4-1. Pin Use Summary (Sheet 5 of 17)
VF-BGA
Ball#
(13x13)
PBGA
Ball#
(23x23)
Name
Type
Function
After
Reset
AC14
Y12
GPIO<52
>
ICOC
Z
GPIO<52>
GPIO<53
>
ICOC
Z
GPIO<53>
GPIO<54
>
ICOC
Z
GPIO<54>
GPIO<55
>
ICOC
Z
GPIO<55>
GPIO<56
>
ICOC
Z
GPIO<56>
GPIO<57
>
ICOC
Z
GPIO<57>
GPIO<81
>
ICOC
Z
GPIO<81>
GPIO<82
>
ICOC
Z
GPIO<82>
GPIO<83
>
ICOC
Z
GPIO<83>
GPIO<84
>
ICOC
Z
GPIO<84>
GPIO<85
>
ICOC
Z
GPIO<85>
GPIO<14
>
ICOC
Z
GPIO<14>
GPIO<19
>
ICOC
Z
GPIO<19>
GPIO<58
>
ICOC
Z
GPIO<58>
GPIO<59
>
ICOC
Z
GPIO<59>
GPIO<60
>
ICOC
Z
GPIO<60>
AB14
AA14
AA10
AB11
AC11
AB12
AD9
AD10
AA11
AC12
AA12
AB13
W9
AB8
AB9
W10
AA8
AB10
Y10
AA10
Primary
Function
Secondary
Alternate
Function
Third
Alternate
Function
CIF_DD<4>
SSPSCLK<3>
—
BB_OB_CLK
SSPSCLK<3>
—
FFRXD
USB_P2_3
—
BB_OB_STB
CIF_MCLK
SSPSYSCL
K
—
BB_OB_WAIT
CIF_PCLK
nPCE<2>
—
CIF_DD<1>
BB_IB_DAT<1>
—
—
nPREG
—
nPWAIT
BB_IB_DAT<2>
—
USB_P3_4
—
—
nIOIS16
BB_IB_DAT<3>
—
—
—
SSPTXD
—
CIF_DD<0>
—
SSPTXD3
BB_OB_DAT<0
>
—
SSPRXD3
BB_IB_DAT<0>
CIF_DD<5>
—
—
FFDTR
SSPSFRM3
BB_IB_CLK
CIF_DD<4>
SSPSFRM3
FFTXD
FFRTS
SSPSCLK3
BB_IB_STB
CIF_FV
SSPSCLK3
—
CIF_FV
FFRXD
DREQ<2>
CIF_LV
nPCE<1>
BB_IB_WAIT
CIF_LV
L_VSYNC
SSPSFRM2
—
—
SSPSFRM2
UCLK
SSPSCLK2
—
FFRXD
SSPSCLK2
L_CS
nURST
—
LDD<0>
—
—
LDD<0>
—
—
LDD<1>
—
—
LDD<1>
—
—
LDD<2>
—
—
LDD<2>
—
Reset
State
Sleep
State
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pu-1
Note[1]
Note [5]
Pu-1
Note[1]
Note [5]
Pu-1
Note[1]
Note [5]
Pu-1
Note[1]
Note [3]
Pu-1
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
VCC_LCD
T24
R22
G24
G22
G23
P20
P19
G20
H20
G21
NOTE: Refer to Table 4-2 for Numbered Notes on Reset and Sleep States.
4-14
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Table 4-1. Pin Use Summary (Sheet 6 of 17)
VF-BGA
Ball#
(13x13)
PBGA
Ball#
(23x23)
Name
Type
Function
After
Reset
H24
F22
GPIO<61
>
ICOC
Z
GPIO<61>
GPIO<62
>
ICOC
Z
GPIO<62>
GPIO<63
>
ICOC
Z
GPIO<63>
GPIO<64
>
ICOC
Z
GPIO<64>
GPIO<65
>
ICOC
Z
GPIO<65>
GPIO<66
>
ICOC
Z
GPIO<66>
GPIO<67
>
ICOC
Z
GPIO<67>
GPIO<68
>
ICOC
Z
GPIO<68>
GPIO<69
>
ICOC
Z
GPIO<69>
GPIO<70
>
ICOC
Z
GPIO<70>
GPIO<71
>
ICOC
Z
GPIO<71>
GPIO<72
>
ICOC
Z
GPIO<72>
GPIO<73
>
ICOC
Z
GPIO<73>
GPIO<74
>
ICOC
Z
GPIO<74>
GPIO<75
>
ICOC
Z
GPIO<75>
GPIO<76
>
ICOC
Z
GPIO<76>
GPIO<77
>
ICOC
Z
GPIO<77>
H22
H23
J22
K24
K22
K23
L21
L23
M24
L22
N24
M22
R23
P23
P22
R21
G22
J20
H22
K20
J19
K19
K21
J22
K22
L20
L21
L22
N22
N20
N21
P21
Primary
Function
Secondary
Alternate
Function
Third
Alternate
Function
—
LDD<3>
—
—
LDD<3>
—
—
LDD<4>
—
—
LDD<4>
—
—
LDD<5>
—
—
LDD<5>
—
—
LDD<6>
—
—
LDD<6>
—
—
LDD<7>
—
—
LDD<7>
—
—
LDD<8>
—
—
LDD<8>
—
—
LDD<9>
—
—
LDD<9>
—
—
LDD<10>
—
—
LDD<10>
—
—
LDD<11>
—
—
LDD<11>
—
—
LDD<12>
—
—
LDD<12>
—
—
LDD<13>
—
—
LDD<13>
—
—
LDD<14>
—
—
LDD<14>
—
—
LDD<15>
—
—
LDD<15>
—
—
—
—
—
L_FCLK_RD
—
—
—
—
—
L_LCLK _A0
—
—
—
—
—
L_PCLK_WR
—
—
—
—
—
L_BIAS
—
Reset
State
Sleep
State
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
NOTE: Refer to Table 4-2 for Numbered Notes on Reset and Sleep States.
Electrical, Mechanical, and Thermal Specification
4-15
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Table 4-1. Pin Use Summary (Sheet 7 of 17)
VF-BGA
Ball#
(13x13)
PBGA
Ball#
(23x23)
Name
Type
Function
After
Reset
N22
M20
GPIO<86
>
ICOC
Z
GPIO<86>
GPIO<87
>
ICOC
Z
GPIO<87>
GPIO<11
>
ICOC
Z
GPIO<11>
GPIO<12
>
ICOC
Z
GPIO<12>
GPIO<13
>
ICOC
Z
GPIO<13>
N23
M22
Primary
Function
Secondary
Alternate
Function
Third
Alternate
Function
SSPRXD2
LDD<16>
USB_P3_5
nPCE<1>
LDD<16>
—
nPCE<2>
LDD<17>
USB_P3_1
SSPTXD2
LDD<17>
SSPSFRM2
EXT_SYNC<0>
SSPRXD2
USB_P3_1
CHOUT<0>
PWM_OUT2
48_MHz
EXT_SYNC<1>
CIF_DD<7>
—
CHOUT<1>
PWM_OUT3
48_MHz
CLK_EXT
KP_DKIN<7>
KP_MKIN<
7>
SSPTXD2
—
—
KP_MKIN<5>
—
—
—
PWM_OUT<0>
FFTXD
KP_MKIN<6>
CIF_DD<6>
—
—
PWM_OUT<1>
—
SSPEXTCLK2
SSPSCLKEN2
SSPSCLK2
KP_MKOUT<7
>
SSPSYSCLK2
—
SSPSCLK
—
CIF_MCLK
SSPSCLK
—
CIF_FV
SSPSFRM
—
CIF_FV
SSPSFRM
—
CIF_LV
—
—
CIF_LV
SSPTXD
—
SSPRXD
CIF_PCLK
FFCTS
—
—
—
SSPEXTCLK
SSPSCLKEN
CIF_DD<0>
SSPSYSCLK
—
FFRTS
AC97_BITCLK
I2S_BITCLK
SSPSFRM
I2S_BITCLK
—
SSPSFRM
AC97_SDATA_I
N_0
I2S_SDATA_IN
SSPSCLK
SSPRXD2
—
SSPSCLK
Reset
State
Sleep
State
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
VCC_IO
C11
B10
C10
A18
C16
D13
B16
A17
D16
B15
C15
A14
B13
A8
A7
A6
C14
D15
A12
A16
B14
A15
A14
C13
D12
A11
GPIO<16
>
ICOC
Z
GPIO<16>
GPIO<17
>
ICOC
Z
GPIO<17>
GPIO<22
>
ICOC
Z
GPIO<22>
GPIO<23
>
ICOC
Z
GPIO<23>
GPIO<24
>
ICOC
Z
GPIO<24>
GPIO<25
>
ICOC
Z
GPIO<25>
GPIO<26
>
ICOC
Z
GPIO<26>
GPIO<27
>
ICOC
Z
GPIO<27>
GPIO<28
>
ICOC
Z
GPIO<28>
GPIO<29
>
ICOC
Z
GPIO<29>
SSPSCLK2
Pd-0
Note[1]
Pd-0
Note[1]
Note
[3],
Note[11
Note
[3],
Note[11
Pd-0
Note[1]
Note
[3],
Note[11
]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
NOTE: Refer to Table 4-2 for Numbered Notes on Reset and Sleep States.
4-16
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Table 4-1. Pin Use Summary (Sheet 8 of 17)
VF-BGA
Ball#
(13x13)
PBGA
Ball#
(23x23)
Name
Type
Function
After
Reset
C13
B11
GPIO<30
>
ICOC
Z
GPIO<30>
GPIO<31
>
ICOC
Z
GPIO<31>
GPIO<32
>
ICOC
Z
GPIO<32>
GPIO<34
>
ICOC
Z
GPIO<34>
GPIO<35
>
ICOC
Z
GPIO<35>
GPIO<36
>
ICOC
Z
GPIO<36>
C12
A20
A21
B19
C14
A15
B14
D19
D14
C18
C21
C22
B20
C19
C11
C16
B19
D17
B13
D13
A13
B17
C12
A19
D20
B21
A20
C17
GPIO<37
>
ICOC
Z
Primary
Function
Secondary
Alternate
Function
Third
Alternate
Function
—
—
—
I2S_SDATA_O
UT
AC97_SDATA_
OUT
USB_P3_2
—
—
—
I2S_SYNC
AC97_SYNC
USB_P3_6
—
—
—
MSSCLK
MMCLK
—
FFRXD
KP_MKIN<3>
SSPSCLK3
USB_P2_2
—
SSPSCLK3
FFCTS
USB_P2_1
SSPSFRM3
—
KP_MKOUT<6
>
SSPTXD3
FFDCD
SSPSCLK2
KP_MKIN<
7>
USB_P2_4
SSPSCLK2
—
FFDSR
SSPSFRM2
KP_MKIN<
3>
USB_P2_8
SSPSFRM2
FFTXD
FFRI
KP_MKIN<4>
USB_P2_3
SSPTXD3
SSPTXD2
PWM_OUT
<1>
KP_MKIN<4>
—
SSPSFRM3
USB_P2_6
FFTXD
SSPSFRM3
SSPRXD2
—
USB_P2_5
KP_MKOUT<6
>
FFDTR
SSPSCLK3
GPIO<37>
GPIO<38
>
ICOC
Z
GPIO<38>
GPIO<39
>
ICOC
Z
GPIO<39>
GPIO<40
>
ICOC
Z
GPIO<40>
GPIO<41
>
ICOC
Z
GPIO<41>
GPIO<42
>
ICOC
Z
GPIO<42>
GPIO<43
>
ICOC
Z
GPIO<43>
GPIO<44
>
ICOC
Z
GPIO<44>
GPIO<45
>
ICOC
Z
GPIO<45>
FFRXD
USB_P2_7
SSPRXD3
KP_MKOUT<7
>
FFRTS
—
BTRXD
ICP_RXD
—
—
—
CIF_MCLK
—
—
CIF_FV
ICP_TXD
BTTXD
CIF_FV
BTCTS
—
CIF_LV
—
—
CIF_LV
—
—
CIF_PCLK
AC97_SYSCLK
BTRTS
SSPSYSCL
K3
Reset
State
Sleep
State
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
NOTE: Refer to Table 4-2 for Numbered Notes on Reset and Sleep States.
Electrical, Mechanical, and Thermal Specification
4-17
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Table 4-1. Pin Use Summary (Sheet 9 of 17)
VF-BGA
Ball#
(13x13)
PBGA
Ball#
(23x23)
Name
Type
Function
After
Reset
B11
A9
GPIO<46
>
ICOC
Z
GPIO<46>
GPIO<47
>
ICOC
Z
GPIO<47>
GPIO<88
>
ICOC
Z
GPIO<88>
GPIO<89
>
ICOC
Z
GPIO<89>
GPIO<92
>
ICOC
Z
GPIO<92>
GPIO<93
>
ICOC
Z
GPIO<93>
GPIO<94
>
ICOC
Z
GPIO<94>
GPIO<95
>
ICOC
Z
A11
C23
D22
A19
AB19
AD19
AA18
AC19
AA17
AD18
AB18
AC18
AC17
AB17
C10
C22
C21
A18
Y16
AA17
AB18
W16
Y15
AA16
AB17
AA15
AB16
Y14
ICOC
Z
GPIO<96>
GPIO<97
>
ICOC
Z
GPIO<97>
GPIO<99
>
ICOC
Z
ICOC
Z
Secondary
Alternate
Function
Third
Alternate
Function
ICP_RXD
STD_RXD
—
—
PWM_OUT<2>
—
CIF_DD<0>
—
—
STD_TXD
ICP_TXD
PWM_OUT
<3>
USBHPWR<1>
SSPRXD2
SSPSFRM2
—
—
SSPSFRM2
SSPRXD3
—
FFRI
AC97_SYSCLK
USBHPEN<1>
SSPTXD2
MMDAT<0>
—
—
MMDAT<0>
MSBS
—
KP_DKIN<0>
CIF_DD<6>
—
AC97_SDATA_
OUT
—
—
KP_DKIN<1>
CIF_DD<5>
—
AC97_SYNC
—
—
KP_DKIN<2>
CIF_DD<4>
KP_MKIN<
6>
GPIO<95>
GPIO<96
>
GPIO<98
>
Primary
Function
AC97_RESET_
n
—
—
KP_DKIN<3>
MBREQ
FFRXD
DVAL<1>
KP_MKOUT
<6>
KP_DKIN<4>
DREQ<1>
KP_MKIN<
3>
—
MBGNT
—
KP_DKIN<5>
CIF_DD<0>
KP_MKIN<
4>
AC97_SYSCLK
—
FFRTS
KP_DKIN<6>
AC97_SDATA_I
N_1
KP_MKIN<
5>
—
—
FFTXD
KP_MKIN<0>
DREQ<2>
FFCTS
—
—
—
KP_MKIN<1>
—
—
—
—
—
KP_MKIN<2>
—
FFRXD
nPCE<1>
—
—
GPIO<98>
GPIO<99>
GPIO<10
0>
ICOC
Z
GPIO<100>
GPIO<10
1>
ICOC
Z
GPIO<101>
GPIO<10
2>
ICOC
Z
GPIO<102>
Reset
State
Sleep
State
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0 Note
[1]
Note [3]
Pd-0 Note
[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
NOTE: Refer to Table 4-2 for Numbered Notes on Reset and Sleep States.
4-18
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Table 4-1. Pin Use Summary (Sheet 10 of 17)
VF-BGA
Ball#
(13x13)
PBGA
Ball#
(23x23)
Name
Type
Function
After
Reset
AC16
AB15
GPIO<10
3>
ICOC
Z
GPIO<103>
GPIO<10
4>
ICOC
Z
GPIO<104>
GPIO<10
5>
ICOC
Z
GPIO<105>
GPIO<10
6>
ICOC
Z
GPIO<106>
GPIO<10
7>
ICOC
Z
GPIO<107>
GPIO<10
8>
ICOC
Z
GPIO<108>
GPIO<10
9>
ICOC
Z
GPIO<109>
GPIO<11
0>
ICOC
Z
AD15
AB16
AB15
AC15
AD14
D17
B17
C17
B18
A13
D24
W14
Y13
W13
AB14
AA13
D16
C15
A17
B16
A10
F19
GPIO<11
1>
E21
GPIO<112>
GPIO<11
3>
ICOC
Z
GPIO<113>
GPIO<11
5>
Note [17]
Third
Alternate
Function
CIF_DD<3>
—
—
—
KP_MKOUT<0
>
—
CIF_DD<2>
—
—
PSKTSEL
KP_MKOUT<1
>
—
CIF_DD<1>
—
—
nPCE<2>
KP_MKOUT<2
>
—
CIF_DD<9>
—
—
—
KP_MKOUT<3
>
—
CIF_DD<8>
—
—
—
KP_MKOUT<4
>
—
CIF_DD<7>
—
—
CHOUT<0>
KP_MKOUT<5
>
—
MMDAT<1>
MSSDIO
—
MMDAT<1>
MSSDIO
—
MMDAT<2>/
MMCCS<0>
—
—
MMDAT<2>/
MMCCS<0>
—
—
MMDAT<3>/
MMCCS<1>
—
—
MMDAT<3>/
MMCCS<1>
—
—
MMCMD
nMSINS
—
MMCMD
—
—
—
—
USB_P3_3
I2S_SYSCLK
AC97_RESET_
n
—
CIFDD_<1>
—
—
UVS0
—
DREQ<0>
CIF_DD<3>
MBREQ
UEN
nUVS1
PWM_OUT
<1>
GPIO<111>
ICOC
Z
GPIO<11
4>
Secondary
Alternate
Function
GPIO<110>
GPIO<11
2>
Note [17]
E21
ICOC
Z
Primary
Function
ICOC
Z
GPIO<114>
ICOC
Z
GPIO<115>
Note [17]
Note [17]
Reset
State
Sleep
State
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pd-0
Note[1]
Note [3]
Pu-1
Note[1]
Note [3]
NOTE: Refer to Table 4-2 for Numbered Notes on Reset and Sleep States.
Electrical, Mechanical, and Thermal Specification
4-19
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Table 4-1. Pin Use Summary (Sheet 11 of 17)
VF-BGA
Ball#
(13x13)
PBGA
Ball#
(23x23)
Name
Type
Function
After
Reset
C24
E20
GPIO<11
6>
ICOC
Z
GPIO<116>
D20
A22
C18
B20
GPIO<11
7>
ICOC
Z
GPIO<11
8>
ICOC
Z
GPIO<118>
Primary
Function
Secondary
Alternate
Function
Third
Alternate
Function
CIF_DD<2>
AC97_SDATA_I
N_0
UDET
DVAL<0>
nUVS2
MBGNT
SCL
—
—
GPIO<117>
SCL
—
—
SDA
—
—
Reset
State
Sleep
State
Pu-1
Note[1]
Note [3]
Pu-1
Note[1]
SDA
—
—
Pu-1
Note[1]
Note
[3],
Note[12
]
Note
[3],
Note[12
]
VCC_USB
B22
D18
USBC_P
IAOA
Z
USBC_P
USBC_P
—
—
Hi-Z
Hi-Z
C20
E19
USBC_N
IAOA
Z
USBC_N
USBC_N
—
—
Hi-Z
Hi-Z
E22
E22
USBH_P
<1>
IAOA
Z
USBH_P<1
>
USBH_P<1>
—
—
Hi-Z
Hi-Z
D23
D22
USBH_N
<1>
IAOA
Z
USBH_N<1
>
USBH_N<1>
—
—
Hi-Z
Hi-Z
GPIO<90
>
ICOC
Z
KP_MKIN<5>
USB_P3_5
CIF_DD<4>
H19
GPIO<90>
nURST
—
Pd-0
Note[1]
Note [3]
—
GPIO<91
>
ICOC
Z
KP_MKIN<6>
USB_P3_1
CIF_DD<5>
GPIO<91>
UCLK
—
Pd-0
Note[1]
Note [3]
—
F20
UIO
ICOC
Z
UIO
UIO
—
—
Driven
Low
Hi-Z
V22
U20
GPIO<0>
ICOC
Z
GPIO<0>
GPIO<0>
—
—
Pd-0
Note[1]
Note [3]
Y24
U21
GPIO<1>
ICOC
Z
GPIO<1>
GPIO<1>
—
—
Pu-1
Note[1]
Note [7]
W21
V22
GPIO<3>
ICOC
Z
GPIO<3>
PWR_SCL
—
—
Pu-1
Note[1]
Hi-Z
W23
T19
GPIO<4>
ICOC
Z
GPIO<4>
PWR_SDA
—
—
Pu-1
Note[1]
Hi-Z
U22
T22
Pd-0
Note[1]
Note [7]
VCC_USIM
F22
F23
E23
G19
VCC_REG
V23
U22
GPIO<9>
Note [18]
GPIO<10
>
Note [18]
ICOC
Z
GPIO<9>
—
—
FFCTS
Note [18]
HZ_CLK
—
CHOUT<0>
GPIO<10>
FFDCD
—
USB_P3_5
Pd-0
Note[1]
Note [7]
ICOC
Z
HZ_CLK
—
CHOUT<1>
Pd-0
Note[1]
Note [7]
Note [18]
NOTE: Refer to Table 4-2 for Numbered Notes on Reset and Sleep States.
4-20
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Table 4-1. Pin Use Summary (Sheet 12 of 17)
VF-BGA
Ball#
(13x13)
PBGA
Ball#
(23x23)
Name
Type
Function
After
Reset
Primary
Function
Secondary
Alternate
Function
Third
Alternate
Function
Reset
State
Sleep
State
W24
T21
CLK_RE
Q
ICOC
Z
CLK_REQ
CLK_REQ
—
—
Pu-1
Note [8]
Y22
W20
NRESET
IC
nRESET
nRESET
—
—
Input Note [9]
Input
Y21
W21
NRESET
_OUT
OC
nRESET_O
UT
nRESET_OUT
—
—
Low
Note [8]
AB23
V19
BOOT_S
EL
IC
BOOT_SEL
BOOT_SEL
—
—
Input
Input
Y23
W22
PWR_EN
OC
PWR_EN
PWR_EN
—
—
Note[16]
Note [8]
AB24
U19
NBATT_F
AULT
IC
nBATT_FAU
LT
nBATT_FAULT
—
—
Low
Input
W22
V20
NVDD_F
AULT
IC
nVDD_FAU
LT
nVDD_FAULT
—
—
Low
Input
AA24
V21
SYS_EN
ICOC
Z
SYS_EN
SYS_EN
—
—
—
Note [7]
AB21
Y19
PWR_CA
P<0>
OA
—
PWR_CAP<0>
—
—
—
Note [7]
AD22
AA21
PWR_CA
P<1>
OA
—
PWR_CAP<1>
—
—
—
Note [7]
AC22
Y18
PWR_CA
P<2>
OA
—
PWR_CAP<2>
—
—
—
Note [7]
AA20
W17
PWR_CA
P<3>
OA
—
PWR_CAP<3>
—
—
—
Note [7]
U21
T20
NTRST
IC
nTRST
nTRST
—
—
Input Note [9]
Input
U23
R22
TDI
IC
TDI
TDI
—
—
Input Note [9]
Input
V24
R21
TDO
OCZ
TDO
TDO
—
—
Hi-Z
Hi-Z
T21
R20
TMS
IC
TMS
TMS
—
—
Input Note [9]
Input
T22
R19
TCK
IC
TCK
TCK
—
—
Input
Input
T23
P22
TESTCLK
IC
TESTCLK
TESTCLK
—
—
Pd-0
Input
AC21
AB20
PXTAL_I
N
IA
PXTAL_IN
PXTAL_IN
—
—
Note[2]
Note [2]
AD21
AA20
PXTAL_O
UT
OA
PXTAL_OU
T
PXTAL_OUT
—
—
Note[2]
Note [2]
AA22
Y21
TXTAL_I
N
IA
TXTAL_IN
TXTAL_IN
—
—
Note[2]
Note [2]
AA23
Y22
TXTAL_O
UT
OA
TXTAL_OU
T
TXTAL_OUT
—
—
Note[2]
Note [2]
AB22
W19
PWR_OU
T
OA
PWR_OUT
PWR_OUT
—
—
Hi-Z
Hi-Z
VCC_OSC
NOTE: Refer to Table 4-2 for Numbered Notes on Reset and Sleep States.
Electrical, Mechanical, and Thermal Specification
4-21
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Table 4-1. Pin Use Summary (Sheet 13 of 17)
VF-BGA
Ball#
(13x13)
PBGA
Ball#
(23x23)
Name
Type
Function
After
Reset
Primary
Function
Secondary
Alternate
Function
Third
Alternate
Function
Reset
State
Sleep
State
AB20
Y17
VCC_BAT
T
PS
VCC_BATT
VCC_BATT
—
—
Input
Input
A12
B10
VCC_IO
PS
VCC_IO
VCC_IO
—
—
Input
Input
AD17
W15
VCC_IO
PS
VCC_IO
VCC_IO
—
—
Input
Input
A16
D14
VCC_IO
PS
VCC_IO
VCC_IO
—
—
Input
Input
B24
A21
VCC_US
B
PS
VCC_USB
VCC_USB
—
—
Input
Input
A24
A22
VCC_US
B
PS
VCC_USB
VCC_USB
—
—
Input
Input
A23
B22
VCC_US
B
PS
VCC_USB
VCC_USB
—
—
Input
Input
B23
D19
VCC_US
B
PS
VCC_USB
VCC_USB
—
—
Input
Input
P24
M19
VCC_LC
D
PS
VCC_LCD0
VCC_LCD
—
—
Input
Input
J24
J21
VCC_LC
D
PS
VCC_LCD1
VCC_LCD
—
—
Input
Input
P1
B2
VCC_ME
M
PS
VCC_MEM
VCC_MEM
—
—
Input
Input
C3
C3
VCC_ME
M
PS
VCC_MEM
VCC_MEM
—
—
Input
Input
E2
C6
VCC_ME
M
PS
VCC_MEM
VCC_MEM
—
—
Input
Input
L3
C9
VCC_ME
M
PS
VCC_MEM
VCC_MEM
—
—
Input
Input
AD2
F3
VCC_ME
M
PS
VCC_MEM
VCC_MEM
—
—
Input
Input
AC2
H3
VCC_ME
M
PS
VCC_MEM
VCC_MEM
—
—
Input
Input
AC1
K3
VCC_ME
M
PS
VCC_MEM
VCC_MEM
—
—
Input
Input
AD1
M3
VCC_ME
M
PS
VCC_MEM
VCC_MEM
—
—
Input
Input
M1
P3
VCC_ME
M
PS
VCC_MEM
VCC_MEM
—
—
Input
Input
H1
T3
VCC_ME
M
PS
VCC_MEM
VCC_MEM
—
—
Input
Input
F1
V3
VCC_ME
M
PS
VCC_MEM
VCC_MEM
—
—
Input
Input
AD8
Y3
VCC_ME
M
PS
VCC_MEM
VCC_MEM
—
—
Input
Input
SUPPLIES
NOTE: Refer to Table 4-2 for Numbered Notes on Reset and Sleep States.
4-22
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Table 4-1. Pin Use Summary (Sheet 14 of 17)
VF-BGA
Ball#
(13x13)
PBGA
Ball#
(23x23)
Name
Type
Function
After
Reset
Primary
Function
Secondary
Alternate
Function
Third
Alternate
Function
Reset
State
Sleep
State
U2
Y5
VCC_ME
M
PS
VCC_MEM
VCC_MEM
—
—
Input
Input
AA2
Y7
VCC_ME
M
PS
VCC_MEM
VCC_MEM
—
—
Input
Input
AC8
Y9
VCC_ME
M
PS
VCC_MEM
VCC_MEM
—
—
Input
Input
B8
AA2
VCC_ME
M
PS
VCC_MEM
VCC_MEM
—
—
Input
Input
A4
N/A
VCC_ME
M
PS
VCC_MEM
VCC_MEM
—
—
Input
Input
AC6
N/A
VCC_ME
M
PS
VCC_MEM
VCC_MEM
—
—
Input
Input
W2
N/A
VCC_ME
M
PS
VCC_MEM
VCC_MEM
—
—
Input
Input
AD12
AA11
VCC_BB
PS
VCC_BB
VCC_BB
—
—
Input
Input
AC20
AB19
VCC_PLL
PS
VCC_PLL
VCC_PLL
—
—
Input
Input
A9
B4
VCC_SR
AM
PS
VCC_SRA
M
VCC_SRAM
—
—
Input
Input
A8
B7
VCC_SR
AM
PS
VCC_SRA
M
VCC_SRAM
—
—
Input
Input
A5
B8
VCC_SR
AM
PS
VCC_SRA
M
VCC_SRAM
—
—
Input
Input
B4
C5
VCC_SR
AM
PS
VCC_SRA
M
VCC_SRAM
—
—
Input
Input
B12
D11
VCC_CO
RE
PS
VCC_COR
E
VCC_CORE
—
—
Input
Input
A7
E6
VCC_CO
RE
PS
VCC_COR
E
VCC_CORE
—
—
Input
Input
D3
E8
VCC_CO
RE
PS
VCC_COR
E
VCC_CORE
—
—
Input
Input
J23
F5
VCC_CO
RE
PS
VCC_COR
E
VCC_CORE
—
—
Input
Input
L24
H5
VCC_CO
RE
PS
VCC_COR
E
VCC_CORE
—
—
Input
Input
F24
L4
VCC_CO
RE
PS
VCC_COR
E
VCC_CORE
—
—
Input
Input
AD16
E15
VCC_CO
RE
PS
VCC_COR
E
VCC_CORE
—
—
Input
Input
R24
E17
VCC_CO
RE
PS
VCC_COR
E
VCC_CORE
—
—
Input
Input
M23
F18
VCC_CO
RE
PS
VCC_COR
E
VCC_CORE
—
—
Input
Input
B21
H18
VCC_CO
RE
PS
VCC_COR
E
VCC_CORE
—
—
Input
Input
NOTE: Refer to Table 4-2 for Numbered Notes on Reset and Sleep States.
Electrical, Mechanical, and Thermal Specification
4-23
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Table 4-1. Pin Use Summary (Sheet 15 of 17)
VF-BGA
Ball#
(13x13)
PBGA
Ball#
(23x23)
Name
Type
Function
After
Reset
Primary
Function
Secondary
Alternate
Function
Third
Alternate
Function
Reset
State
Sleep
State
W3
L19
VCC_CO
RE
PS
VCC_COR
E
VCC_CORE
—
—
Input
Input
AD4
R5
VCC_CO
RE
PS
VCC_COR
E
VCC_CORE
—
—
Input
Input
T2
U5
VCC_CO
RE
PS
VCC_COR
E
VCC_CORE
—
—
Input
Input
AD11
V6
VCC_CO
RE
PS
VCC_COR
E
VCC_CORE
—
—
Input
Input
N/A
V8
VCC_CO
RE
PS
VCC_COR
E
VCC_CORE
—
—
Input
Input
N/A
W11
VCC_CO
RE
PS
VCC_COR
E
VCC_CORE
—
—
Input
Input
N/A
R18
VCC_CO
RE
PS
VCC_COR
E
VCC_CORE
—
—
Input
Input
N/A
U18
VCC_CO
RE
PS
VCC_COR
E
VCC_CORE
—
—
Input
Input
N/A
V15
VCC_CO
RE
PS
VCC_COR
E
VCC_CORE
—
—
Input
Input
N/A
V17
VCC_CO
RE
PS
VCC_COR
E
VCC_CORE
—
—
Input
Input
E24
F21
VCC_USI
M
PS
VCC_USIM
VCC_USIM
—
—
Input
Input
AA21
W18
VSS
PS
VSS
VSS
—
—
Input
Input
AC24
Y20
VSS
PS
VSS
VSS
—
—
Input
Input
AD24
AA22
VSS
PS
VSS
VSS
—
—
Input
Input
AC23
AB21
VSS
PS
VSS
VSS
—
—
Input
Input
AD23
AB22
VSS
PS
VSS
VSS
—
—
Input
Input
V21
N/A
VSS
PS
VSS
VSS
—
—
Input
Input
D11
B12
VSS_IO
PS
VSS_IO
VSS_IO
—
—
Input
Input
AA19
B15
VSS_IO
PS
VSS_IO
VSS_IO
—
—
Input
Input
D15
B18
VSS_IO
PS
VSS_IO
VSS_IO
—
—
Input
Input
N21
D21
VSS_IO
PS
VSS_IO
VSS_IO
—
—
Input
Input
AA16
H21
VSS_IO
PS
VSS_IO
VSS_IO
—
—
Input
Input
H21
M21
VSS_IO
PS
VSS_IO
VSS_IO
—
—
Input
Input
F21
N19
VSS_IO
PS
VSS_IO
VSS_IO
—
—
Input
Input
D18
AA14
VSS_IO
PS
VSS_IO
VSS_IO
—
—
Input
Input
U24
AA18
VSS_IO
PS
VSS_IO
VSS_IO
—
—
Input
Input
D5
A1
VSS_ME
M
PS
VSS_MEM
VSS_MEM
—
—
Input
Input
F4
A2
VSS_ME
M
PS
VSS_MEM
VSS_MEM
—
—
Input
Input
NOTE: Refer to Table 4-2 for Numbered Notes on Reset and Sleep States.
4-24
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Table 4-1. Pin Use Summary (Sheet 16 of 17)
VF-BGA
Ball#
(13x13)
PBGA
Ball#
(23x23)
Name
Type
Function
After
Reset
Primary
Function
Secondary
Alternate
Function
Third
Alternate
Function
Reset
State
Sleep
State
H4
B1
VSS_ME
M
PS
VSS_MEM
VSS_MEM
—
—
Input
Input
J4
B3
VSS_ME
M
PS
VSS_MEM
VSS_MEM
—
—
Input
Input
AC3
B6
VSS_ME
M
PS
VSS_MEM
VSS_MEM
—
—
Input
Input
AB2
B9
VSS_ME
M
PS
VSS_MEM
VSS_MEM
—
—
Input
Input
L4
F2
VSS_ME
M
PS
VSS_MEM
VSS_MEM
—
—
Input
Input
T4
H2
VSS_ME
M
PS
VSS_MEM
VSS_MEM
—
—
Input
Input
V4
L2
VSS_ME
M
PS
VSS_MEM
VSS_MEM
—
—
Input
Input
AA5
P2
VSS_ME
M
PS
VSS_MEM
VSS_MEM
—
—
Input
Input
AA8
T2
VSS_ME
M
PS
VSS_MEM
VSS_MEM
—
—
Input
Input
AA9
V2
VSS_ME
M
PS
VSS_MEM
VSS_MEM
—
—
Input
Input
D9
AA1
VSS_ME
M
PS
VSS_MEM
VSS_MEM
—
—
Input
Input
N4
AA6
VSS_ME
M
PS
VSS_MEM
VSS_MEM
—
—
Input
Input
R2
AA9
VSS_ME
M
PS
VSS_MEM
VSS_MEM
—
—
Input
Input
C5
AB1
VSS_ME
M
PS
VSS_MEM
VSS_MEM
—
—
Input
Input
Y4
AB2
VSS_ME
M
PS
VSS_MEM
VSS_MEM
—
—
Input
Input
AA13
AB11
VSS_BB
PS
VSS_BB
VSS_BB
—
—
Input
Input
AD20
AA19
VSS_PLL
PS
VSS_PLL
VSS_PLL
—
—
Input
Input
B2
E5
VSS_CO
RE
PS
VSS_CORE
VSS_CORE
—
—
Input
Input
A2
E7
VSS_CO
RE
PS
VSS_CORE
VSS_CORE
—
—
Input
Input
B1
E9
VSS_CO
RE
PS
VSS_CORE
VSS_CORE
—
—
Input
Input
A1
G5
VSS_CO
RE
PS
VSS_CORE
VSS_CORE
—
—
Input
Input
J21
J5
VSS_CO
RE
PS
VSS_CORE
VSS_CORE
—
—
Input
Input
D10
E14
VSS_CO
RE
PS
VSS_CORE
VSS_CORE
—
—
Input
Input
NOTE: Refer to Table 4-2 for Numbered Notes on Reset and Sleep States.
Electrical, Mechanical, and Thermal Specification
4-25
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Table 4-1. Pin Use Summary (Sheet 17 of 17)
VF-BGA
Ball#
(13x13)
PBGA
Ball#
(23x23)
Name
Type
Function
After
Reset
Primary
Function
Secondary
Alternate
Function
Third
Alternate
Function
Reset
State
Sleep
State
AA15
E16
VSS_CO
RE
PS
VSS_CORE
VSS_CORE
—
—
Input
Input
M21
E18
VSS_CO
RE
PS
VSS_CORE
VSS_CORE
—
—
Input
Input
U3
G18
VSS_CO
RE
PS
VSS_CORE
VSS_CORE
—
—
Input
Input
AA7
J18
VSS_CO
RE
PS
VSS_CORE
VSS_CORE
—
—
Input
Input
P21
P5
VSS_CO
RE
PS
VSS_CORE
VSS_CORE
—
—
Input
Input
K21
T5
VSS_CO
RE
PS
VSS_CORE
VSS_CORE
—
—
Input
Input
G21
V5
VSS_CO
RE
PS
VSS_CORE
VSS_CORE
—
—
Input
Input
D21
V7
VSS_CO
RE
PS
VSS_CORE
VSS_CORE
—
—
Input
Input
D12
V9
VSS_CO
RE
PS
VSS_CORE
VSS_CORE
—
—
Input
Input
D8
P18
VSS_CO
RE
PS
VSS_CORE
VSS_CORE
—
—
Input
Input
W4
T18
VSS_CO
RE
PS
VSS_CORE
VSS_CORE
—
—
Input
Input
AA12
V14
VSS_CO
RE
PS
VSS_CORE
VSS_CORE
—
—
Input
Input
B5
V16
VSS_CO
RE
PS
VSS_CORE
VSS_CORE
—
—
Input
Input
D7
V18
VSS_CO
RE
PS
VSS_CORE
VSS_CORE
—
—
Input
Input
NOTE: Refer to Table 4-2 for Numbered Notes on Reset and Sleep States.
4-26
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Pin Listing and Signal Definitions
4.3
Signal Types
Table 4-2. Pin Use and Mapping Notes
Note
Description
[1]
GPIO reset/deep sleep operation: After any reset is asserted or if the PXA270 processor is in deep sleep mode, these
pins are configured as GPIO inputs by default. The input buffers for these pins are disabled to prevent current drain and
must be enabled prior to use by clearing the read disable hold bit, PSSR[RDH]. Until RDH is cleared, each pin is pulled
high (Pu-1), pulled low (Pd-0), or floated (Hi-Z).
[2]
Crystal oscillator pins: These pins connect the external crystals to the on-chip oscillators and are not affected by either
reset or sleep. For more information, see the “Clocks and Power” chapter in the Intel® PXA27x Processor Family
Developer’s Manual.
GPIO sleep operation: During the transition into sleep mode, the configuration of these pins is determined by the
corresponding GPIO setting. This pin is not driven during sleep if the direction of the pin is selected to be an input. If the
direction of the pin is selected as an output, the value contained in the Power Manager GPIO Sleep-State register
(PGSR0/1/2/3) is driven out onto the pin and held while the PXA270 processor is in sleep mode.
[3]
Upon exit from sleep mode, GPIOs that are configured as outputs continue to hold the standby, sleep, or deep-sleep state
until software clears the peripheral control hold bit, PSSR[PH]. Software must clear this bit (by writing 0b1 to it) after the
peripherals have been fully configured, as described in Note[1], but before the process actually uses them.
GPIOs that are configured as inputs immediately after exiting sleep mode cannot be used until PSSR[RDH] is cleared.
[4]
Static memory control pins: During sleep mode, these pins can be programmed either to drive the value in the Power
Manager GPIO Sleep-State register (PGSR0/1/2/3) or to be placed in a Hi-Z (undriven) state. To select the Hi-Z state,
software must set PCFR[FS]. If FS is not set, these pins function as described in Note[3] during the transition to sleep
mode.
[5]
PCMCIA control pins: During sleep mode, these pins can be programmed either to drive the value in the Power Manager
GPIO Sleep-State register (PGSR0/1/2/3) or to be placed in a Hi-Z (undriven) state. To select the Hi-Z state, software
must set PCFR[FP]. If FP is not set, these pins function as described in Note[3] during the transition to sleep mode.
[6]
(reserved)
[7]
When the power manager overrides the GPIO alternate function, the Power Manager GPIO Sleep-State registers
(PGSR0/1/2/3) and the PSSR[RDH] bit are ignored. Pullup and pulldown are disabled immediately after the power
manager overrides the GPIO function.
[8]
Output functions during sleep mode
[9]
Pull-up always enabled
[10]
(reserved)
[11]
Pins do not function during sleep mode if the OS timer is active
[12]
Pins must be floated by software during sleep mode (floating does not happen automatically)
[13]
(reserved)
[14]
(reserved)
[15]
The pin is three-stateable (Hi-Z) based on the value of PCFR[FS]. There is no PGSR0/1/2/3 setting associated with the
pin because it is not a GPIO.
[16]
PWR_EN goes high during reset, between the assertion of the reset pin and the de-assertion of internal reset within the
PXA270 processor, after SYS_EN is driven high.
[17]
GPIOs 114 and115: The alternate function configuration of these pins is ignored when either PUCR[USIM114] or
PUCR[USIM115] bits are set. Setting these bits forces the USIM enable signal onto these GPIOs.
[18]
When software sets the OSCC[PIO_EN] or OSCC[TOUT_EN] bits, then any GPIO alternate function setting applied to
GPIO<9> or GPIO <10> is overridden with the CLK_PIO function on GPIO<9> and CLK_TOUT on GPIO<10>.
[19]
Refer to Table 4-4.
Electrical, Mechanical, and Thermal Specification
4-27
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Table 4-3. Signal Types
Type
4.4
Description
IC
CMOS input
OC
CMOS output
OCZ
CMOS output, three-stateable
ICOCZ
CMOS bidirectional, three-stateable
IA
Analog input
OA
Analog output
IAOA
Analog bidirectional
IAOAZ
Analog bidirectional - three-stateable
PS
Power supply
Memory Controller Reset and Initialization
On reset, the SDRAM interface is disabled. Reset values for the boot ROM are determined by
BOOT_SEL (see the Intel® PXA27x Processor Family Developers Manual, Memory Controller
chapter). Boot ROM is immediately available for reading upon exit from reset, and all memory
interface control registers are available for writing.
On hardware reset, the memory pins and controller are in the state shown in Table 4-4.
Table 4-4. Memory Controller Pin Reset Values (Sheet 1 of 2)
Pin Name
4-28
Reset, Sleep, Standby, Deep-Sleep, Frequency
Change, and Manual Self-Refresh Mode Values
SDCLK <31:0>
0b000
SDCKE
0
DQM <3:0>
0b0000
nSDCS <3:2>
GPIO (memory controller drives 0b11)†
nSDCS <1:0>
0b11
nWE
1
nSDRAS
1
nSDCAS
1
nOE
1
MA <25:0>
0x0000_00001
RDnWR
0
MD <31:0>
0x0000_00002
nCS <0>
1
nCS <5:1>
GPIO (memory controller drives 0b11111)
nPIOIR
GPIO (memory controller drives high)
nPIOIW
GPIO (memory controller drives high)
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Pin Listing and Signal Definitions
Table 4-4. Memory Controller Pin Reset Values (Sheet 2 of 2)
Pin Name
Reset, Sleep, Standby, Deep-Sleep, Frequency
Change, and Manual Self-Refresh Mode Values
nPOE
GPIO (memory controller drives high)
nPWE
GPIO (memory controller drives high)
NOTE:
This indicates that the GPIO pin, if configured for the alternate function
used by the memory controller during reset, drives the represented
value.
NOTE: SCLK<3> is only available on PXA270 processor family packages
1. MA pins are driven
2. MD pins are pulled low
†
The address signals are driven low and data signals are pulled low during sleep, standby, deepsleep, frequency-change modes, and manual self-refresh. All other memory control signals are in
the same state that they are in after a hardware reset. If the SDRAMs are in self-refresh mode, they
are kept there by driving SDCKE low.
4.5
Power-Supply Pins
Table 4-5 summarize the power-supply ball count.
Table 4-5. Discrete (13x13 VF-BGA) Power Supply Pin Summary
Number of Package Balls
13x13 mm VF-BGA
Number of Pachage Balls
23x23 mm PBGA
VCC_BATT
1
1
VCC_IO
3
3
Name
VCC_USB
4
4
VCC_LCD
2
2
VCC_MEM
19
16
VCC_BB
1
1
VCC_PLL
1
1
VCC_SRAM
4
4
VCC_CORE
14
20
VCC_USIM
1
1
VSS
6
5
VSS_IO
9
9
VSS_MEM
17
17
VSS_BB
1
1
VSS_PLL
1
1
VSS_CORE
56
56
§§
Electrical, Mechanical, and Thermal Specification
4-29
Intel® PXA270 Processor
Pin Listing and Signal Definitions
4-30
Electrical, Mechanical, and Thermal Specification
5
Electrical Specifications
5.1
Absolute Maximum Ratings
The absolute maximum ratings (shown in Table 5-1) define limitations for electrical and thermal
stresses. These limits prevent permanent damage to the Intel® PXA270 processor.
Note:
Absolute maximum ratings are not operating ranges.
Table 5-1. Absolute Maximum Ratings
Symbol
Description
Min
Max
Units
TS
Storage temperature
–40
125
°C
–0.3
0.3
V
–0.3
0.3
V
–0.3
0.3
V
–0.3
0.3
V
–0.3
0.3
V
VCC_OL1
VCC_OL2
VCC_OH1
VCC_OH2
Offset voltage between any of the following pins:
VCC_CORE
Offset voltage between any of the following pins:
VCC_SRAM
Offset voltage between any of the following pins:
VCC_MEM
Offset voltage between any of the following pins:
VCC_IO
VCC_OH3
Offset voltage between VCC_LCD<0> and VCC_LCD<1>
VCC_HV
Voltage applied to high-voltage supply pins
(VCC_BB, VCC_USB, VCC_USIM, VCC_MEM,
VCC_IO<, VCC_LCD)
VSS–0.3
VSS+4.0
V
VCC_LV
Voltage applied to low-voltage supply pins
(VCC_CORE, VCC_PLL, VCC_SRAM)
VSS–0.3
VSS+1.45
V
VIP
Voltage applied to non-supply pins except PXTAL_IN,
PXTAL_OUT, TXTAL_IN, and TXTAL_OUT pins
VSS–0.3
VSS+4.0
V
VIP_X
Voltage applied to XTAL pins
(PXTAL_IN, PXTAL_OUT, TXTAL_IN, TXTAL_OUT)
VSS–0.3
VSS+1.45
V
—
2000
V
—
5
mA
Maximum ESD stress voltage, three stresses maximum:
VESD
• Any pin to any supply pin, either polarity, or
• Any pin to all non-supply pins together, either polarity
IEOS
5.2
Maximum DC input current (electrical overstress) for any
non-supply pin
Operating Conditions
This section shows operating voltage, frequency, and temperature specifications for the PXA270
processor.
Electrical, Mechanical, and Thermal Specification
5-1
Intel® PXA270 Processor
Electrical Specifications
Table 5-2 shows each power domains supported voltages (except for VCC_MEM and
VCC_CORE). Table 5-3 shows all of the supported memory voltages and frequency operating
ranges (VCC_MEM). Table Note: shows all of the supported core voltage and frequency ranges
(VCC_CORE).
The operating temperature specification is a function of voltage and frequency.
Table 5-2. Voltage, Temperature, and Frequency Electrical Specifications (Sheet 1 of 2)
Symbol
Description
Min
Typical
Max
Units
Package operating temperature†
(Standard Temp)
-25
—
+85
Package operating temperature†
(Extended Temp - PBGA ONLY)
-40
—
+85
Junction-to-case temperature gradient
(VF-BGA)
—
2
—
Junction-to-case temperature gradient
(PBGA)
—
1.4
—
2.25
3.00
3.75
V
Operating Temperature
Tcase
°C
°C /
watt
Theta Jc
VCC_BATT Voltage
VVCC0
Voltage applied on VCC_BATT @3.0V
VVDF1
Voltage difference between VCC_BATT
and VCC_IO during power-on reset or
deep-sleep wake-up (from the assertion
of SYS_EN to the de-assertion of
nRESET_OUT)
0
—
0.30
V
VVDF2
Voltage difference between VCC_BATT
and VCC_IO when VCC_IO is enabled
0
—
0.20
V
Tbramp
Ramp Rate
—
10
12
mV/uS
1.17
1.30
1.43
V
—
10
12
mV/uS
1.71
1.80
2.16
V
2.25
2.50
2.75
V
2.70
3.0
3.30
V
2.97
3.3
3.63
V
—
10
12
mV/uS
VCC_PLL Voltage
VVCC1
Tpwrramp
Voltage applied on VCC_PLL @1.3V
(+10 / -10%)
Ramp Rate
VCC_BB Voltages
VVCC2a
VVCC2b
VVCC2c
VVCC2d
Tsysramp
Voltage applied on VCC_BB @1.8V
(+20 / -5%)
Voltage applied on VCC_BB @2.5V
(+10 / -10%)
Voltage applied on VCC_BB @3.0V
(+10 / -10%)
Voltage applied on VCC_BB @3.3V
(+10 / -10%)
Ramp Rate
NOTE: VCC_BB may optionally be tied to the same PMIC regulator as VCC_IO if the system design allows
both VCC_IO and VCC_BB to use the same voltage level. This allows the GPIO’s on VCC_BB to be
used at the same voltage level.
VCC_LCD Voltages
5-2
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Electrical Specifications
Table 5-2. Voltage, Temperature, and Frequency Electrical Specifications (Sheet 2 of 2)
Symbol
VVCC3a
VVCC3b
VVCC3c
VVCC3d
Tsysramp
Description
Voltage applied on VCC_LCD @1.8V
(+20 / -5%)
Voltage applied on VCC_LCD @2.5V
(+10 / -10%)
Voltage applied on VCC_LCD @3.0V
(+10 / -10%)
Voltage applied on VCC_LCD @3.3V
(+10 / -10%)
Ramp Rate
Min
Typical
Max
Units
1.71
1.80
2.16
V
2.25
2.50
2.75
V
2.70
3.0
3.30
V
2.97
3.3
3.63
V
—
10
12
mV/uS
2.69175
3.0
3.30
V
2.97
3.3
3.63
V
—
10
12
mV/uS
VCC_IO Voltages
VVCC4a
VVCC4b
Tsysramp
Voltage applied on VCC_IO @3.0V
(+10 / -10.3%)
Voltage applied on VCC_IO @3.3V
(+10 / -10%)
Ramp Rate
NOTE: VCC_IO must be maintained at a voltage as high as or higher than, all other supplies except for
VCC_BATT and VCC_USB
VCC_USIM Voltages
VVCC5a
VVCC5b
Tsysramp
Voltage applied on VCC_USIM @1.8V
(+20 / -5%)
Voltage applied on VCC_USIM @3.0V
(+10 / -10%)
Ramp Rate
1.71
1.80
2.16
V
2.70
3.0
3.30
V
—
10
12
mV/uS
NOTE: If the system does NOT use the USIM module, VCC_USIM can be tied to VCC_IO (at any supported
VCC_IO voltage level). This allows the GPIO’s on VCC_USIM to be used at the same voltage level as
VCC_IO GPIO’s. NOTE: Software must NOT configure USIM signals to be used if this is done.
VCC_SRAM Voltage
VVCC6
Tpwrramp
Voltage applied on VCC_SRAM @1.1V
(+10 / -10%)
Ramp Rate
0.99
1.10
1.21
V
—
10
12
mV/uS
2.70
3.00
3.30
V
2.97
3.30
3.63
V
—
10
12
mV/uS
VCC_USB Voltage
VVCC7a
VVCC7b
Tsysramp
†
Voltage applied on VCC_USB @3.0V
(+10 / -10%)
Voltage applied on VCC_USB @3.3V
(+10 / -10%)
Ramp Rate
System design must ensure that the device case temperature is maintained within the specified limits. In
some system applications, it may be necessary to use external thermal management (for example, a
package-mounted heat spreader) or configure the device to limit power consumption and maintain
acceptable case temperatures.
Table 5-3 shows the supported memory frequency and memory supply voltage operating ranges for
the PXA270 processor.
Electrical, Mechanical, and Thermal Specification
5-3
Intel® PXA270 Processor
Electrical Specifications
Table 5-3. Memory Voltage and Frequency Electrical Specifications
Symbol
Description
Min
Typical
Max
Units
1.71
1.80
2.16
V
Memory Voltage and Frequency Range 1
VMEM1
Voltage applied on VCC_MEM
fSM1A
External synchronous memory frequency,
SDCLK1, SDCLK2
13
—
104
MHz
fSM1B
External synchronous memory frequency,
SDCLK0
13
—
104
MHz
Tsysramp
Ramp Rate
—
10
12
mV/uS
2.25
2.50
2.75
V
Memory Voltage and Frequency Range 2
VMEM2
Voltage applied on VCC_MEM
fSM2A
External synchronous memory frequency,
SDCLK1, SDCLK2
13
—
104
MHz
fSM2B
External synchronous memory frequency,
SDCLK0
13
—
104
MHz
Tsysramp
Ramp Rate
—
10
12
mV/uS
2.70
3.0
3.3
V
Memory Voltage and Frequency Range 3
VMEM3
Voltage applied on VCC_MEM
fSM3A
External synchronous memory frequency,
SDCLK1, SDCLK2
13
—
104
MHz
fSM3B
External synchronous memory frequency,
SDCLK0
13
—
104
MHz
Tsysramp
Ramp Rate
—
10
12
mV/uS
Memory Voltage and Frequency Range 4
VMEM4
Voltage applied on VCC_MEM
2.97
3.30
3.63
V
fSM4A
External synchronous memory frequency,
SDCLK1, SDCLK2
13
—
104
MHz
fSM4B
External synchronous memory frequency,
SDCLK0
13
—
104
MHz
Tsysramp
Ramp Rate
—
10
12
mV/uS
Table 5-4 shows the supported core frequency and core supply voltage operating ranges for the
PXA270 processor. Each frequency range is specified in the following format:
(core frequency/internal system bus frequency/memory controller frequency/SDRAM frequency)
Note:
Refer to the “Clocks and Power” section of the Intel® PXA27x Processor Family Developers
Manual for supported frequencies, clock register settings as listed in Table 5-4.
Table 5-4. Core Voltage and Frequency Electrical Specifications (Sheet 1 of 2)
Symbol
Description
Min
Typical
Max
Units
Core Voltage and Frequency Range 1 (13/13/13/13 CCCR[CPDIS]=1, CCCR[PPDIS]=1)
5-4
VVCCC1
Voltage applied on VCC_CORE
0.8075
0.85
1.705
V
fCORE1
Core operating frequency
13
—
13
MHz
Tpwrramp
Ramp Rate
—
10
12
mV/uS
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Electrical Specifications
Table 5-4. Core Voltage and Frequency Electrical Specifications (Sheet 2 of 2)
Core Voltage and Frequency Range 2 (13/13/13/13 CCCR[CPDIS]=1, CCCR[PPDIS]=0), (91/45.5/91/45.5),
and (104/104/104/104)
VVCCC2
Voltage applied on VCC_CORE
0.855
0.9
1.705
V
fCORE2
Core operating frequency
91
—
104
MHz
Tpwrramp
Ramp Rate
—
10
12
mV/uS
0.95
1.00
1.705
V
Core Voltage and Frequency Range 3 (156/104/104/104)
VVCCC3
Voltage applied on VCC_CORE
fCORE3
Core operating frequency
—
156
—
MHz
Tpwrramp
Ramp Rate
—
10
12
mV/uS
Core Voltage and Frequency Range 4 (208/208/208/104) and (208/208/104/104)
VVCCC4
Voltage applied on VCC_CORE
1.12
1.18
1.705
V
fCORE4
Core operating frequency
—
208
—
MHz
Tpwrramp
Ramp Rate
—
10
12
mV/uS
0.9975
1.05
1.705
V
Core Voltage and Frequency Range 4a (208/104/104/104)
VVCCC4a
Voltage applied on VCC_CORE
fCORE4a
Core operating frequency
—
208
—
MHz
Tpwrramp
Ramp Rate
—
10
12
mV/uS
Core Voltage and Frequency Range 5 (312/208/208/104) and (312/208/104/104)
VVCCC5
Voltage applied on VCC_CORE
1.1875
1.25
1.705
V
fCORE5
Core operating frequency
—
312
—
MHz
Tpwrramp
Ramp Rate
—
10
12
mV/uS
0.99
1.1
1.705
V
Core Voltage and Frequency Range 5a (312/104/104/104)
VVCCC5a
Voltage applied on VCC_CORE
fCORE5a
Core operating frequency
—
312
—
MHz
Tpwrramp
Ramp Rate
—
10
12
mV/uS
Core Voltage and Frequency Range 6 (416/208/208/104) amd (416/208/104/104)
VVCCC6
Voltage applied on VCC_CORE
1.2825
1.35
1.705
V
fCORE6
Core operating frequency
—
416
—
MHz
Tpwrramp
Ramp Rate
—
10
12
mV/uS
Core Voltage and Frequency Range 7 (520/208/208/104) and (520/208/104/104)
VVCCC7
Voltage applied on VCC_CORE
1.3775
1.45
1.705
V
fCORE7
Core operating frequency
—
520
—
MHz
Tpwrramp
Ramp Rate
—
10
12
mV/uS
Core Voltage and Frequency Range 8 (624/208/208/104) and (624/208/104/104)
VVCCC8
Voltage applied on VCC_CORE
1.4725
1.55
1.705
V
fCORE8
Core operating frequency
—
624
—
MHz
Tpwrramp
Ramp Rate
—
10
12
mV/uS
†Core operating frequency not offered in PBGA package.
Electrical, Mechanical, and Thermal Specification
5-5
Intel® PXA270 Processor
Electrical Specifications
5.2.1
Internal Power Domains
The external power supplies are used to generate several internal power domains, which are shown
in Table 5-5. Refer to the Power Manager / Internal Power Domain Block Diagram in the “Clocks
and Power” section of the Intel® PXA27x Processor Family Developers Manual for more
information on internal power domains.
Table 5-5. Internally Generated Power Domain Descriptions
Name
Units
Generation
Tolerance
VCC_REG
IO associated with deep-sleepactive units
Switched between VCC_BATT and VCC_IO
VCC_OSC
Oscillator power supplies
Generated from VCC_REG
VCC_RTC
RTC and power manager
supply
Switched between VCC_OSC and
VCC_CORE
-
Power manager I2C supply
Switched between VCC_OSC and
VCC_CORE
-
VCC_CPU
CPU core
Independent power-down from VCC_CORE
-
VCC_PER
Peripheral units
Independent power-down from VCC_CORE
-
Particular internal SRAM unit
Switched between VCC_OSC and
VCC_SRAM
-
VCC_PI
VCC_Rx
+/- 30%
Table 5-6 shows the recommended core voltage specification for each of the lower power modes.
Table 5-6. Core Voltage Specifications For Lower Power Modes
5.3
Mode
Description
Min
Typical
Max
Units
Standby
Voltage applied on VCC_CORE
1.045
1.1
1.21
V
Deep-Idle
Voltage applied on VCC_CORE
0.8075
0.85
0.935
V
Power-Consumption Specifications
Power consumption depends on the operating voltage and frequency, peripherals enabled, external
switching activity, and external loading and other factors.
Use these specifications as a guideline for power consumption capacity. These typical guidelines
vary across different platforms and software applications.
Table 5-7 contains three sets of power consumption information: Active Power Consumption, Idle
Power Consumption, and Low-Power Modes Power Consumption.
The data set are projected numbers based off of measured data at room temperature. For Active
Power Consumption data, no peripherals are enabled except for UART.
Table 5-8 contains idle and low power mode maximum power consumption information based on
experimental and manufacturing test limits.
5-6
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Electrical Specifications
Table 5-7. Typical Power-Consumption Specifications (Sheet 1 of 2)
Parameter Description
Typical
Units
Conditions
624 MHz Active Power (208 MHz System bus)
925
mW
VCC_CORE = 1.55V VCC_SRAM = 1.1V
VCC_PLL = 1.3V VCC_MEM, VCC_BB,
VCC_USIM, VCC_LCD = 1.8V
VCC_IO, VCC_BATT, VCC_USB= 3.0V
520 MHz Active Power (208 MHz System bus)
747
mW
VCC_CORE = 1.45V VCC_SRAM = 1.1V
VCC_PLL = 1.3V VCC_MEM, VCC_BB,
VCC_USIM, VCC_LCD = 1.8V
VCC_IO, VCC_BATT, VCC_USB= 3.0V
416 MHz Active Power (208 MHz System bus)
570
mW
VCC_CORE = 1.35V VCC_SRAM = 1.1V
VCC_PLL = 1.3V VCC_MEM, VCC_BB,
VCC_USIM, VCC_LCD = 1.8V
VCC_IO, VCC_BATT, VCC_USB= 3.0V
312 MHz Active Power (208 MHz System bus)
390
mW
VCC_CORE = 1.25V VCC_SRAM = 1.1V
VCC_PLL = 1.3V VCC_MEM, VCC_BB,
VCC_USIM, VCC_LCD = 1.8V
VCC_IO, VCC_BATT, VCC_USB= 3.0V
312 MHz Active Power (104 MHz System bus)
375
mW
VCC_CORE = 1.1V VCC_SRAM = 1.1V
VCC_PLL = 1.3V VCC_MEM, VCC_BB,
VCC_USIM, VCC_LCD = 1.8V
VCC_IO, VCC_BATT, VCC_USB= 3.0V
208 MHz Active Power (208 MHz System bus)
279
mW
VCC_CORE = 1.15V VCC_SRAM = 1.1V
VCC_PLL = 1.3V VCC_MEM, VCC_BB,
VCC_USIM, VCC_LCD = 1.8V
VCC_IO, VCC_BATT, VCC_USB= 3.0V
104 MHz Active Power (104 MHz System bus)
116
mW
VCC_CORE = 0.9V VCC_SRAM = 1.1V
VCC_PLL = 1.3V VCC_MEM, VCC_BB,
VCC_USIM, VCC_LCD = 1.8V
VCC_IO, VCC_BATT, VCC_USB= 3.0V
13 MHz Active Power (CCCR[CPDIS=1)
44.2
mW
VCC_CORE = 0.85V VCC_SRAM = 1.1V
VCC_PLL = 1.3V VCC_MEM, VCC_BB,
VCC_USIM, VCC_LCD = 1.8V
VCC_IO, VCC_BATT, VCC_USB= 3.0V
624 MHz Idle Power (208 MHz System bus)
260
mW
VCC_CORE = 1.55V VCC_SRAM = 1.1V
VCC_PLL = 1.3V VCC_MEM, VCC_BB,
VCC_USIM, VCC_LCD = 1.8V
VCC_IO, VCC_BATT, VCC_USB= 3.0V
520 MHz Idle Power (208 MHz System bus)
222
mW
VCC_CORE = 1.45V VCC_SRAM = 1.1V
VCC_PLL = 1.3V VCC_MEM, VCC_BB,
VCC_USIM, VCC_LCD = 1.8V
VCC_IO, VCC_BATT, VCC_USB= 3.0V
416 MHz Idle Power (208 MHz System bus)
186
mW
VCC_CORE = 1.35V VCC_SRAM = 1.1V
VCC_PLL = 1.3V VCC_MEM, VCC_BB,
VCC_USIM, VCC_LCD = 1.8V
VCC_IO, VCC_BATT, VCC_USB= 3.0V
312 MHz Idle Power (208 MHz System bus)
154
mW
VCC_CORE = 1.25V VCC_SRAM = 1.1V
VCC_PLL = 1.3V VCC_MEM, VCC_BB,
VCC_USIM, VCC_LCD = 1.8V
VCC_IO, VCC_BATT, VCC_USB= 3.0V
312 MHz Idle Power (104 MHz System bus)
109
mW
VCC_CORE = 1.1V VCC_SRAM = 1.1V
VCC_PLL = 1.3V VCC_MEM, VCC_BB,
VCC_USIM, VCC_LCD = 1.8V
VCC_IO, VCC_BATT, VCC_USB= 3.0V
208 MHz Idle Power (208 MHz System bus)
129
mW
VCC_CORE = 1.15V VCC_SRAM = 1.1V
VCC_PLL = 1.3V VCC_MEM, VCC_BB,
VCC_USIM, VCC_LCD = 1.8V
VCC_IO, VCC_BATT, VCC_USB= 3.0V
104 MHz Idle Power (104 MHz System bus)
64
mW
VCC_CORE = 0.9V VCC_SRAM = 1.1V
VCC_PLL = 1.3V VCC_MEM, VCC_BB,
VCC_USIM, VCC_LCD = 1.8V
VCC_IO, VCC_BATT, VCC_USB= 3.0V
Active Power Consumption
Idle Power Consumption
Electrical, Mechanical, and Thermal Specification
5-7
Intel® PXA270 Processor
Electrical Specifications
Table 5-7. Typical Power-Consumption Specifications (Sheet 2 of 2)
Parameter Description
Typical
Units
Conditions
13 MHz Idle Mode1 Power (LCD on)
15.4
mW
VCC_CORE, VCC_SRAM, VCC_PLL = 0.85V
VCC_MEM, VCC_BB, VCC_USIM,
VCC_LCD = 1.8V
VCC_IO, VCC_BATT, VCC_USB= 3.0V
13 MHz Idle Mode1 Power (LCD off)
8.5
mW
VCC_CORE, VCC_SRAM, VCC_PLL = 0.85V
VCC_MEM, VCC_BB, VCC_USIM,
VCC_LCD = 1.8V
VCC_IO, VCC_BATT, VCC_USB= 3.0V
Deep-Sleep mode
0.1014
mW
VCC_CORE, VCC_SRAM, VCC_PLL = 0V
VCC_MEM, VCC_BB, VCC_USIM,
VCC_LCD = 1.8V
VCC_IO, VCC_BATT, VCC_USB= 3.0V
Sleep mode
0.1630
mW
VCC_CORE, VCC_SRAM, VCC_PLL = 0V
VCC_MEM, VCC_BB, VCC_USIM,
VCC_LCD = 1.8V
VCC_IO, VCC_BATT, VCC_USB= 3.0V
Standby mode
1.7224
mW
VCC_CORE, VCC_SRAM, VCC_PLL = 1.1V
VCC_MEM, VCC_BB, VCC_USIM,
VCC_LCD = 1.8V
VCC_IO, VCC_BATT, VCC_USB= 3.0V
Low Power modes Power Consumption
NOTE: 1) 13 MHz Idle Mode (CCCR[CPDIS] =1 (CCCR[PPDIS] = 1)
Table 5-8. Maximum Idle and Low Power Mode Power-Consumption Specifications
Parameter Description
Maximum
Units
Conditions
624 MHz Idle Current on VCC_CORE
(PX=208 MHz)
770
mA
Temp=85C Tcase,
VCC_CORE=VCC_SRAM=VCC_PLL=1.705
V, VCC_PERI1=3.63V, VCC_IO=3.63V,
VCC_BATT=3.75V
520 MHz Idle Current on VCC_CORE
(PX=208 MHz)
630
mA
Temp=85C Tcase,
VCC_CORE=VCC_SRAM=VCC_PLL=1.595
V, VCC_PERI=3.63V, VCC_IO=3.63V,
VCC_BATT=3.75V
416 MHz Idle Current on VCC_CORE
(PX=208 MHz)
500
mA
Temp=85C Tcase,
VCC_CORE=VCC_SRAM=VCC_PLL=1.485
V, VCC_PERI=3.63V, VCC_IO=3.63V,
VCC_BATT=3.75V
312 MHz Idle Current on VCC_CORE
(PX=208 MHz)
380
mA
Temp=85C Tcase,
VCC_CORE=VCC_SRAM=VCC_PLL=1.375
V, VCC_PERI=3.63V, VCC_IO=3.63V,
VCC_BATT=3.75V
208 MHz Idle Current on VCC_CORE
(PX=208 MHz)
260
mA
Temp=85C Tcase,
VCC_CORE=VCC_SRAM=VCC_PLL=1.265
V, VCC_PERI=3.63V, VCC_IO=3.63V,
VCC_BATT=3.75V
104 MHz Idle Current on VCC_CORE
(PX=104 MHz)
150
mA
Temp=85C Tcase,
VCC_CORE=VCC_SRAM=VCC_PLL=0.99V,
VCC_PERI=3.63V, VCC_IO=3.63V,
VCC_BATT=3.75V
Idle Current on VCC_PERI1, All Core Speeds
200
mA
Temp=85C Tcase,
VCC_CORE=VCC_SRAM=VCC_PLL=any,
VCC_PERI=3.63V, VCC_IO=3.63V,
VCC_BATT=3.75V
Idle Current on VCC_IO, All Core Speeds
50
mA
Temp=85C Tcase,
VCC_CORE=VCC_SRAM=VCC_PLL=any,
VCC_PERI=3.63V, VCC_IO=3.63V,
VCC_BATT=3.75V
Idle Mode Power Consumption
Idle Current on VCC_PLL, All Core Speeds
5-8
100
mA
Temp=85C Tcase,
VCC_CORE=VCC_SRAM=VCC_PLL=any,
VCC_PERI=3.63V, VCC_IO=3.63V,
VCC_BATT=3.75V
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Electrical Specifications
Parameter Description
Maximum
Units
Conditions
105
mA
Temp=85C Tcase,
VCC_CORE=VCC_SRAM=VCC_PLL=0.935
V, VCC_PERI=3.63V, VCC_IO=3.63V,
VCC_BATT=3.75V
Standby Current on VCC_CORE
5
mA
Temp=Room,
VCC_CORE=VCC_SRAM=VCC_PLL=1.1V,
VCC_PERI=1.8V, VCC_IO=VCC_BATT=3.0V
Standby Current on VCC_PERI
1.6
mA
Temp=Room,
VCC_CORE=VCC_SRAM=VCC_PLL=1.1V,
VCC_PERI=1.8V, VCC_IO=VCC_BATT=3.0V
1
mA
Temp=Room,
VCC_CORE=VCC_SRAM=VCC_PLL=1.1V,
VCC_PERI=1.8V, VCC_IO=VCC_BATT=3.0V
Sleep Current on VCC_CORE
0.15
mA
Temp=Room, VCC_CORE=VCC_PLL=0V,
VCC_SRAM=0.95V, VCC_PERI=1.8V,
VCC_IO=VCC_BATT=3.0V
Sleep Current on VCC_PERI
0.47
mA
Temp=Room, VCC_CORE=VCC_PLL=0V,
VCC_SRAM=0.95V, VCC_PERI=1.8V,
VCC_IO=VCC_BATT=3.0V
Sleep Current on VCC_IO
0.70
mA
Temp=Room, VCC_CORE=VCC_PLL=0V,
VCC_SRAM=0.95V, VCC_PERI=1.8V,
VCC_IO=VCC_BATT=3.0V
Sleep Current on VCC_PLL
0.043
mA
Temp=Room, VCC_CORE=VCC_PLL=0V,
VCC_SRAM=0.95V, VCC_PERI=1.8V,
VCC_IO=VCC_BATT=3.0V
Deep-Idle Mode Power Consumption
13 MHz Deep Idle Current on VCC_CORE
(LCD off)
Standby Mode Power Consumption
Standby Current on VCC_IO
Sleep Mode Power Consumption
NOTE: 1) VCC_PERI = VCC_MEM + VCC_BB + VCC_USIM + VCC_LCD
5.4
DC Specification
The DC characteristics for each pin include input sense levels, output drive levels, and currents.
These parameters can be used to determine maximum DC loading and to determine maximum
transition times for a given load. Table 5-9 shows the DC operating conditions for the high- and
low-strength input, output, and I/O pins.
Note:
VCC_IO must be maintained at a voltage as high as or higher than all other supplies except
VCC_BATT and VCC_USB.
Table 5-9. Standard Input, Output, and I/O Pin DC Operating Conditions (Sheet 1 of 2)
Symbol
Min
Max
Unit
s
Testing Conditions
/ Notes
Input high voltage, all standard input and I/O
pins, relative to applicable VCC (VCC_IO,
VCC_MEM, VCC_BB, VCC_LCD, or
VCC_USIM)
0.8 * VCC
VCC + 0.1
V
—
Input high voltage for the USB bus voltage
domain (VCC_USB)
0.8 * VCC
3.6
V
—
Description
Input DC Operating Conditions (VCC = 1.8V, 2.5, 3.0, 3.3 Typical)
VIH
1
VIH_USB
Electrical, Mechanical, and Thermal Specification
5-9
Intel® PXA270 Processor
Electrical Specifications
Table 5-9. Standard Input, Output, and I/O Pin DC Operating Conditions (Sheet 2 of 2)
Min
Max
Unit
s
Testing Conditions
/ Notes
VSS - 0.1
0.2 * VCC
V
—
DC Overshoot voltage / duration
—
+1
V
Max duration of 4nS
DC Undershoot voltage / duration
—
-1
V
Max duration of 4nS
Symbol
Description
VIL1
Input low voltage, all standard input and I/O
pins, relative to applicable VSS (VSS_IO,
VSS_MEM, or VSS_BB) and VCC (VCC_IO,
VCC_MEM, VCC_BB, VCC_LCD, VCC_USB,
or VCC_USIM)
OS
US
Output DC Operating Conditions (VCC = 1.8, 2.5, 3.0, 3.3 Typical)
VOH1
Output high voltage, all standard output and I/
O pins, relative to applicable VCC (VCC_IO,
VCC_MEM, VCC_BB, VCC_LCD, VCC_USB,
or VCC_USIM)
VCC - 0.3
VCC
V
VOL1
Output low voltage, all standard output and I/O
pins, relative to applicable VSS (VSS_IO,
VSS_MEM, or VSS_BB)
VSS
VSS + 0.3
V
IOH = -4 mA2,
-3 mA3
IOH = 4 mA2,
3 mA3
NOTES:
1. Programmable drive strengths set to 0x5 for memory and LCD programmable signals.
2. The current for the high-strength pins are MA<25:0>, MD<31:0>, nOE, nWE, nSDRAS, nSDCAS, DQM<3:0>, nSDCS<3:0>,
SDCKE<1>, SDCLK<3:0>, RDnWR, nCS<5:0>, and nPWE.
3. The current for all other output and I/O pins are low strength.
5.5
Oscillator Electrical Specifications
The PXA270 processor contains two oscillators: a 32.768-kHz oscillator and a 13.000-MHz
oscillator. Each oscillator requires a specific crystal.
5.5.1
32.768-kHz Oscillator Specifications
The 32.768-kHz oscillator is connected between the TXTAL_IN (amplifier input) and
TXTAL_OUT (amplified output). Table 5-10 and Table 5-11 list the appropriate 32.768-kHz
specifications.
To drive the 32.768-kHz crystal pins from an external source:
1. Drive the TXTAL_IN pin with a digital signal that has low and high levels as listed in
Table 5-11. Do not exceed VCC_PLL or go below VSS_PLL by more than 100 mV. The
minimum slew rate is 1 volt per 1 µs. The maximum current drawn from the external clock
source when the clock is at its maximum positive voltage is typically 1 mA.
2. Float the TXTAL_OUT pin or drive it in complement to the TXTAL_IN pin, with the same
voltage level and slew rate.
5-10
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Electrical Specifications
Caution:
The TXTAL_IN and TXTAL_OUT pins must not be driven from an external source if the PXA270
processor sleep / deep sleep DC-DC converter is enabled.
Table 5-10. Typical 32.768-kHz Crystal Requirements
Parameter
Minimum
Typical
Maximum
Units
—
32.768
—
kHz
–30
—
+30
ppm
Frequency stability, parabolic coefficient
—
—
–0.04
ppm/
(Δ°C)2
Drive level
—
—
1.0
uW
Load capacitance (CL)
6
7.5
12.5
pf
Shunt capacitance (CO)
—
0.9
—
pf
Motional capacitance (CI)
—
2.1
—
fF
Equivalent series resistance (RS)
—
18
65
kΩ
Insulation resistance at 100 VDC
100
—
—
MΩ
—
—
±3.0
ppm
Frequency range
Frequency tolerance
Aging, at operating temperature per year
Electrical, Mechanical, and Thermal Specification
5-11
Intel® PXA270 Processor
Electrical Specifications
Table 5-11. Typical External 32.768-kHz Oscillator Requirements
Symbol
Description
Min
Typical
Max
Units
Amplifier Specifications
VIH_X
Input high voltage, TXTAL_IN
0.99
1.10
1.21
V
VIL_X
Input low voltage, TXTAL_IN
–0.10
0.00
0.10
V
IIN_XT
Input leakage, TXTAL_IN
—
—
1
μA
CIN_XT
Input capacitance, TXTAL_IN/
TXTAL_OUT
—
18
25
pf
tS_XT
Stabilization time
—
—
10
s
Board Specifications
5.5.2
RP_XT
Parasitic resistance, TXTAL_IN/
TXTAL_OUT to any node
20
—
—
MΩ
CP_XT
Parasitic capacitance, TXTAL_IN/
TXTAL_OUT, total
—
—
5
pf
COP_XT
Parasitic shunt capacitance,
TXTAL_IN to TXTAL_OUT
—
—
0.4
pf
13.000-MHz Oscillator Specifications
The 13.000-MHz oscillator is connected between the PXTAL_IN (amplifier input) and
PXTAL_OUT (amplified output). Table 5-12 and Table 5-13 list the 13.000-MHz specifications.
To drive the 13.000-MHz crystal pins from an external source:
1. Drive the PXTAL_IN pin with a digital signal with low and high levels as listed in Table 5-13.
Do not exceed VCC_PLL or go below VSS_PLL by more than 100 mV. The minimum slew
rate is 1 volt / 1 ns. The maximum current drawn from the external clock source when the
clock is at its maximum positive voltage typically is 1 mA.
2. Float the PXTAL_OUT pin or drive it in complement to the PXTAL_IN pin, with the same
voltage level, slew rate, and input current restrictions.
Caution:
The PXTAL_IN and PXTAL_OUT pins must not be driven from an external source if the PXA270
processor sleep / deep sleep DC-DC converter is enabled.
Table 5-12. Typical 13.000-MHz Crystal Requirements
Parameter
Minimum
Typical
Maximum
Units
12.997
13.000
13.002
MHz
–50
—
+50
ppm
—
Fnd
—
—
–50
—
+50
ppm
Drive level
—
10
100
uW
Frequency range
Frequency tolerance at 25°C
Oscillation mode
Maximum change over temperature range
5-12
Load capacitance (CL)
—
10
—
pf
Maximum series resistance (RS)
—
50
—
Ω
Aging per year, at operating temperature
—
—
±5.0
ppm
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Electrical Specifications
Table 5-13. Typical External 13.000-MHz Oscillator Requirements
Symbol
Description
Min
Typical
Max
Units
Amplifier Specifications
VIH_X
Input high voltage, PXTAL_IN
0.99
1.10
1.21
V
VIL_X
Input low voltage, PXTAL_IN
–0.10
0.00
0.10
V
IIN_XP
Input leakage, PXTAL_IN
—
—
10
μA
CIN_XP
Input capacitance, PXTAL_IN/PXTAL_OUT
—
40
50
pf
tS_XP
Stabilization time
—
—
67.8
ms
Board Specifications
RP_XP
Parasitic resistance, PXTAL_IN/PXTAL_OUT to
any node
20
—
—
MΩ
CP_XP
Parasitic capacitance, PXTAL_IN/PXTAL_OUT,
total
—
—
5
pf
COP_XP
Parasitic shunt capacitance, PXTAL_IN to
PXTAL_OUT
—
—
0.4
pf
5.6
CLK_PIO and CLK_TOUT Specifications
CLK_PIO can be used to drive a buffered version of the PXTAL_IN oscillator input or can be used
as a clock input alternative to PXTAL_IN. Refer to Table 5-14 for CLK_PIO specifications.
A buffered and inverted version of the TXTAL_IN oscillator output is driven out on CLK_TOUT.
Refer to Table 5-15 for CLK_TOUT specifications.
Note:
CLK_TOUT and CLK_PIO are only available when software sets the OSCC[PIO_EN] and
OSCC[TOUT_EN] bits.
Table 5-14. CLK_PIO Specifications
Parameter
Specifications
Frequency
13 MHz
Frequency Accuracy (derived from 13 MHz crystal)
Symmetry/Duty Cycle variation
Jitter
Load capacitance (CL)
Rise and Fall time (Tr & Tf)
+/-200ppm
30/70 to 70/30% at VCC
+/-20pS max
50pf max
15nS max with 50pF load
Table 5-15. CLK_TOUT Specifications (Sheet 1 of 2)
Parameter
Specifications
Frequency
32 kHz
Frequency Accuracy (derived from 32 kHz crystal)
Symmetry/Duty Cycle variation
Electrical, Mechanical, and Thermal Specification
+/-200ppm
30/70 to 70/30% at VCC
5-13
Intel® PXA270 Processor
Electrical Specifications
Table 5-15. CLK_TOUT Specifications (Sheet 2 of 2)
Parameter
Specifications
Jitter
+/-20pS max
Load capacitance (CL)
Rise and Fall time (Tr & Tf)
5.7
50pf max
15nS max with 50pF load
48 MHz Output Specifications
Software may configure GPIO<11> or GPIO<12> alternate functions to enable the 48-MHz clock
output. The 48-MHz output clock is a divided-down output generated from the 312-MHz
peripheral PLL. Refer to Table 5-16 for the 48-MHz output specifications. Refer to Section 3 of
this document for GPIO alternate functions in the pin usage table.
Table 5-16. 48 MHz Output Specifications
Parameter
Specifications
Frequency (derived from 13 MHz crystal)
Frequency Accuracy (derived from 13 MHz crystal)
Symmetry/Duty Cycle variation
Jitter
Load capacitance (CL)
Rise and Fall time (Tr & Tf)
5-14
48 MHz
+/-200ppm (maximum)
30/70 to 70/30% at VCC
+/-20pS max
50pf max
15nS max with 50pF load
Electrical, Mechanical, and Thermal Specification
6
AC Timing Specifications
A pin’s alternating-current (AC) characteristics include input and output capacitance. These factors
determine the loading for external drivers and other load analyses. The AC characteristics also
include a derating factor, which indicates how much the AC timings might vary with different
loads.
Note:
The timing diagrams in this chapter show bursts that start at 0 and proceed to 3 or 7. However, the
least significant address (0) is not always received first during a burst transfer, because the Intel®
PXA270 processor requests the critical word first during burst accesses.
Table 6-1 shows the AC operating conditions for the high- and low-strength input, output, and I/O
pins. All AC specification values are valid for the device’s entire temperature range.
Table 6-1. Standard Input, Output, and I/O-Pin AC Operating Conditions
6.1
Symbol
Description
Min
Typical
Max
Units
CIN
Input capacitance, all standard input and
I/O pins
—
—
10
pf
COUT_H
Output capacitance, all standard highstrength output and I/O pins
20
—
50
pf
COUT_L
Output capacitance, all standard lowstrength output and I/O pins
20
—
50
pf
AC Test Load Specifications
Figure 6-1 represents the timing reference load used in defining the relevant timing parameters of
the part. It is not intended to be a precise representation of the typical system environment nor a
depiction of the actual load presented by a production tester. System designers use IBIS or other
simulation tools to correlate the timing reference load to system environment. Manufacturers
correlate to their production test conditions (generally a coaxial transmission line terminated at the
tester electronics).
Figure 6-1. AC Test Load
I/O
ΖΟ = 50Ω
Electrical, Mechanical, and Thermal Specification
50pf
6-1
Intel® PXA270 Processor
AC Timing Specifications
6.2
Reset and Power Manager Timing Specifications
The processor asserts the nRESET_OUT pin in one of several different modes:
•
•
•
•
•
•
Power-on reset
Hardware reset
Watchdog reset
GPIO reset
Sleep mode
Deep-sleep mode
The following sections give the timing and specifications for entry into and exit from these modes.
6.2.1
Power-On Timing Specifications
Power-on reset begins when a power supply is detected on the backup battery pin, VCC_BATT,
after the processor has been powered off. A power-on reset is equivalent to a hardware reset, in that
all units are reset to the same known state as with a hardware reset. A power-on reset is a complete
and total reset that occurs only at initial power on.
The external power-supply system must enable the power supplies for the processor in a specific
sequence to ensure proper operation. Figure 6-2 shows the timing diagram for a power-on reset
sequence. Table 6-2 details the timing.
The sequence for power-on reset is as follows:
1. VCC_BATT is established, then nRESET should be de-asserted to initiate power-on reset.
2. PWR_OUT is asserted. The processor asserts nRESET_OUT.
3. The external power-control subsystem de-asserts nBATT_FAULT to signal that the main
battery is connected and not discharged.
4. The processor asserts the SYS_EN signal to enable the power supplies VCC_IO, VCC_MEM,
VCC_BB, VCC_USB, and VCC_LCD. VCC_USIM can be established at this time also but
can be independently controlled through its own control signals. VCC_IO must be established
first. The other supplies can turn on in any order, but they must all be established within
125 milliseconds of the assertion of SYS_EN.
5. The processor asserts the PWR_EN signal to enable the power supplies VCC_CORE,
VCC_SRAM, and VCC_PLL. These supplies can turn on in any order but must all be
established within 125 milliseconds of the assertion of PWR_EN.
6. The external power-control subsystem de-asserts nVDD_FAULT to signal that all system
power supplies have been properly established.
7. The processor de-asserts nRESET_OUT and enters run mode, executing code from the reset
vector.
Note:
6-2
nVDD_FAULT is sampled only when the SYS_DEL and PWR_DEL timers have expired. Refer to
the Intel® PXA27x Processor Family Developer’s Manual, “Initial Power On” and “Deep-Sleep
Exit States” for a state diagram.
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
AC Timing Specifications
Figure 6-2. Power On Reset Timing
t1
t2
t3
t5
VCC_BATT
nBATT_FAULT
tbramp
nRESET
SYS_EN
VCC_USB, VCC_IO, VCC_MEM,
VCC_BB, VCC_LCD, VCC_USIM
PWR_EN
VCC_CORE, VCC_SRAM,
VCC_PLL
tsysramp
tpwrramp
nVDD_FAULT
t4
nRESET_OUT
Table 6-2. Power-On Timing Specifications(OSCC[CRI] = 0)
Symbol
Description
Min
Typical
Max
Units
t1
Delay from VCC_BATT assertion to
nRESET de-assertion
10
—
—
ms
t2
Delay from nRESET de-assertion to
SYS_EN assertion
—
101
—
ms
t3
Delay from SYS_EN assertion to
PWR_EN assertion
—
125
—
ms
t4
Power supply stabilization time (time to
the de-assertion of nVDD_FAULT after
the assertion of PWR_EN)
—
—
120
ms
t5
Delay from the assertion of PWR_EN to
the de-assertion of nRESET_OUT
—
125
—
ms
tbramp
VCC_BATT power-on Ramp Rate
—
10
12
mV/uS
tsysramp
Power-on Ramp Rate for all external high
-voltage power domains
—
10
12
mV/uS
tpwrramp
Power-on Ramp Rate for all external low
-voltage power domains (including
dynamic voltage changes on
VCC_CORE)
—
10
12
mV/uS
NOTES:
1. If the OSCC[CRI] =1 then the delay from nRESET de-assertion to SYS_EN assertion is 3000mS
NOTE: This long delay is attributed to the fact that when the CRI bit is read as 1, (which indicates that the
CLK_REQ pin was floated during a hardware or power-on reset) the processor oscillator is supplied
externally, which then forces the system to wait for the 32 kHz oscillator and the 13 MHz oscillator to
stabilize.
Electrical, Mechanical, and Thermal Specification
6-3
Intel® PXA270 Processor
AC Timing Specifications
6.2.2
Hardware Reset Timing
The timing sequences shown in Figure 6-3 for hardware reset and the specifications in Table 6-3
and Table 6-4 assume stable power supplies at the assertion of nRESET. Follow the timings
indicated in Section 6.2.1 if the power supplies are unstable.
Figure 6-3. Hardware Reset Timing
t7
nRESET
t6
t8
nRESET_OUT
NOTE: nBATT_FAULT and nVDD_FAULT must be deasserted during the reset sequence.
Table 6-3. Hardware Reset Timing Specifications (OSCC[CRI] = 0)
Symbol
Description
Min
Typical
Max
Units
t6
Delay between nRESET asserted and
nRESET_OUT asserted
—
< 100 ns
10
ms
t7
Assertion time of nRESET
6
—
—
ms
t8
Delay between nRESET de-asserted and
nRESET_OUT de-asserted
256
—
265
ms
Min
Typical
Max
Units
Table 6-4. Hardware Reset Timing Specifications (OSCC[CRI] = 1)
6.2.3
Symbol
Description
t6
Delay between nRESET asserted and
nRESET_OUT asserted
—
< 100 ns
10
ms
t7
Assertion time of nRESET
6
—
—
ms
t8
Delay between nRESET de-asserted and
nRESET_OUT de-asserted
2256
—
3265
ms
Watchdog Reset Timing
Watchdog reset is generated internally and therefore has no external pin dependencies. The
SYS_EN and PWR_EN power signals de-assert and the nRESET_OUT pin asserts during
watchdog reset. The timing is similar to that for power-on reset — see Figure 6-2 for details.
6.2.4
GPIO Reset Timing
GPIO reset is generated externally, and the reset GPIO source is reconfigured as a standard GPIO
as soon as the reset propagates internally. The clocks module is not reset by GPIO reset, so the reset
timing varies based on the selected clock frequency. Since GPIO assertions are ignored during a
6-4
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
AC Timing Specifications
frequency change sequence, if GPIO<1> is asserted during a frequency change sequence, it must
remain asserted low for 240 ns after the frequency change completes in order for the GPIO reset to
be recognized. Figure 6-4 shows the timing of GPIO reset, and Table 6-5 shows the GPIO reset
timing specifications.
Note:
When bit GPROD is set in the Power Manager General Configuration register, nRESET_OUT is
not asserted during GPIO reset. For register details, see the “Clocks and Power Manager” chapter
in the Intel® PXA27x Processor Family Developer’s Manual.
Figure 6-4. GPIO Reset Timing
tA_GPIO<1>
GP[1]
nRESET_OUT
tDHW_OUT
nCS0
tDHW_OUT_A
tCS0
Table 6-5. GPIO Reset Timing Specifications (Sheet ? of ?)
Symbol
Description
Min
Typical
Max
Units
Notes
tA_GPIO<1>
Minimum assert time of GPIO<1> in
13.000-MHz input clock cycles
4
—
—
cycles
1, 2, 4
tDHW_OUT_A
Delay between GPIO<1> asserted
and nRESET_OUT asserted in
13.000-MHz input clock cycles
6
—
8
cycles
4
tDHW_OUT
Delay between nRESET_OUT
asserted and nRESET_OUT deasserted, run or turbo mode
230
—
—
nsec
tDHW_OUT_F
Delay between nRESET_OUT
asserted and nRESET_OUT deasserted, during frequency change
sequence
5
—
380
μs
3
tCS0
Delay between nRESET_OUT deassertion and nCS0 assertion
1000
—
—
ns
5
NOTES:
1. GPIO<1> is not recognized as a reset source again until configured to do so in software.
Software must check the state of GPIO<1> before configuring as a reset to ensure that no
spurious reset is generated. For details, see the “Clocks and Power Manager” chapter in the
Intel® PXA27x Processor Family Developer’s Manual.
2. If GPIO<1> reset is asserted during a frequency change sequence, the minimum assert time of
GPIO<1> needs to be 512*N processor clock cycles plus up to 4 cycles of the 13.000-MHz
input clock cycles in order for the reset to be recognized.
3. Time during the frequency-change sequence depends on the state of the PLL lock detector at
the assertion of GPIO reset. The lock detector has a maximum time of 350 µs plus
synchronization.
4. In standby, sleep, and deep-sleep modes, this time is in addition to the wake-up time from the
low-power mode.
5. The tCS0 specification is also applicable to Power-On reset, Hardware reset, Watchdog reset
and Deep-Sleep/Sleep mode exit.
Electrical, Mechanical, and Thermal Specification
6-5
Intel® PXA270 Processor
AC Timing Specifications
6.2.5
Sleep Mode Timing
Sleep mode is internally asserted, and it asserts the nRESET_OUT and PWR_EN signals.
Figure 6-5 and Table 6-6 show the required timing parameters for sleep mode.
Note:
When bit SL_ROD is set in the Power Manager Sleep Configuration register, nRESET_OUT, is
not asserted during sleep mode. See the “Clocks and Power Manager” chapter in the Intel®
PXA27x Processor Family Developer’s Manual for register details.
Figure 6-5. Sleep Mode Timing
Intel® PXA27x State:
SLEEP (ENTRY)
SLEEP
SLEEP (EXIT)
NORMAL
Texit
Wakeup Event
SYS_EN
VCC_USB, VCC_IO,
VCC_BB,VCC_MEM,
VCC_LCD, VCC_USIM
PWR_EN
(High)
(Enabled)
VCC_CORE, VCC_SRAM,
VCC_PLL
Tpwrdelay
Tentry
nVDD_FAULT
nRESET_OUT
Table 6-6. Sleep-Mode Timing Specifications
Symbol
Description
Min
Typical
Max3
Units
tentry5
Delay between MCR sleep command
issue to de-assertion of PWR_EN
0.56
—
2.51
msec
texit
Delay between wakeup event and run
mode
0.50
—
136.652,4
msec
tpwrdelay
Delay between assertion of PWR_EN to
PLL enable2
0
—
125
msec
NOTES:
1. -1mS if not using DC2DC and -0.94mS if any internal SRAM banks are not powered
2. 0.15ms less time if exiting from sleep mode to 13M mode
3. Add 0.1ms if the wake up event is external
4. Oscillator start/crystal stable times are programmable (300uS-11mS)
NOTE: 5ms is user programmable using the OSCC[OSD] bit. The remaining 6ms is an internal timer which
counts until the oscillator is stable. (Typical stabilization is 500μs. Maximum can be upto 5ms)
5. nRESET_OUT and nVDD_FAULT are programmable during sleep mode
6.2.6
Deep-Sleep Mode Timing
Deep-sleep mode is internally asserted, and it asserts the nRESET_OUT and PWR_EN signals.
Figure 6-6 and Table 6-7 show the required timing parameters for sleep mode. The timing
specifications listed are for software-invoked (not battery or VDD fault) deep-sleep entry, unless
specified.
6-6
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
AC Timing Specifications
Figure 6-6. Deep-Sleep-Mode Timing
Intel® PXA27x State:
DEEP SLEEP (ENTRY)
Wakeup Event
DEEP SLEEP
DEEP SLEEP (EXIT)
Tenable
SYS_EN
VCC_USB, VCC_IO,
VCC_BB, VCC_MEM,
VCC_LCD, VCC_USIM
PWR_EN
NORMAL
Tdexit
Tdsys_delay
Tdentry
Tdpwr_delay
VCC_CORE, VCC_SRAM,
VCC_PLL
nVDD_FAULT
nRESET_OUT
Deep-Sleep Command
Table 6-7. Deep-Sleep Mode Timing Specifications
Symbol
Description
Min
Typical
Max3
Units
tdentry5
Delay between deep-sleep command
issue to de-assertion of SYS_EN
0.66
—
1.661
msec
tenable
Delay between de-assertion of PWR_EN
and SYS_EN
—
30
—
usec
tdexit
Delay between wakeup event and run
mode
0.60
—
261.752,4
msec
tdsysdelay
Delay between assertion of SYS_EN to
PWR_EN2
0
—
125
msec
tdpwrdelay
Delay between assertion of PWR_EN to
PLL enable2
0
—
125
msec
NOTE: Timing specifications for nBATT_FAULT and/or nVDD_FAULT asserted deep-sleep mode entry are
below:
Fault assert
Delay between nBATT_FAULT or
nVDD_FAULT assertion (during all
modes of operation including sleep
mode) and deep-sleep mode entry6(The
de-assertion of SYS_EN defines when
the processor is in deep-sleep mode)
0.33
—
1.56
msec
NOTES:
1. -1ms if not using DC2DC
2. 0.15ms less time if exiting from deep-sleep mode to 13M mode
3. Add 0.1ms if the wake up event is external
4. Oscillator start/crystal stable times are programmable (300uS-11mS)
NOTE: 6ms is user programmable using the OSCC[OSD] bit. The remaining 5ms is an internal timer which
counts until the oscillator is stable. (Typical stabilization is 500μs. Maximum can be upto 5ms)
5. nRESET_OUT and nVDD_FAULT are programmable during sleep mode
6. Assumes PMCR[BIDAE or VIDAE] bits are set to zero (default state) - The PMCR[BIDAE or VIDAE] bits
are only read by the processor if nBATT_FAULT or nVDD_FAULT signals are asserted
Electrical, Mechanical, and Thermal Specification
6-7
Intel® PXA270 Processor
AC Timing Specifications
6.2.6.1
GPIO states in Deep-Sleep mode
If the external high voltage power domains (VCC_IO, VCC_MEM, VCC_BB, VCC_LCD,
VCC_USB, VCC_USIM) remain powered on during deep-sleep, the PGSR values are driven onto
all the GPIO pins (that are configured as outputs) for a finite time period, then the pins default to
the reset state (Pu/Pd) as described in Chapter 2 of this manual. This sequence occurs for either
software-initiated or fault-initiated deep-sleep entry.
Note:
GPIOs<0,1,3,4,9,10> never float. They are powered from VCC_BATT so when the system and the
core power domains are removed (controlled by SYS_EN and PWR_EN), the Pu/Pd resistors
remain enabled due to VCC_BATT remaining on.
The delay between the initiation of deep-sleep mode and enabling the GPIO Pu/Pd states is system
dependant because the processor is performing an unpredictable workload and requires an
unknown amount of time to complete current processes. Refer to the deep-sleep mode, “Clocks and
Power” section of the Intel® PXA27x Processor Family Developers Manual for a description on
deep-sleep mode entry sequence.
Table 6-8 shows the time period that the GPIO pullup/pulldowns are enabled. Listed below are the
regulators and converter naming conventions:
L1 = Sleep/Deep-Sleep Linear Regulator
L2 = High-Current Linear Regulator
DC2DC = Sleep/Deep-Sleep DC-DC Converter
Table 6-8. GPIO Pu/Pd Timing Specifications for Deep-Sleep Mode
Note:
6-8
Description
L2
L1
DC2DC
Units
Duration of the GPIO Pu/Pd states being
enabled and the de-assertion of
PWR_EN
0.1
0.13
1.13
msec
If the external high voltage power domains (VCC_IO, VCC_MEM, VCC_BB, VCC_LCD,
VCC_USB, VCC_USIM) are powered off during deep-sleep mode, the GPIOs behave the same as
described above; however, they float after the supplies are removed.
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
AC Timing Specifications
6.2.7
Standby-Mode Timing
Table 6-9. Standby-Mode Timing Specifications
Symbol
Description
Min
Typical
Max
—
0.34
—
—
13M mode to standby mode entry
—
1
Standby mode exit to 13M mode
0.28
—
11.28
—
Run mode to standby mode entry
—
0.34
—
—
1
Standby mode exit to run mode
Units
msec
2
msec
msec
2
0.43
—
11.43
msec
Min
Typical
Max
Units
NOTES:
1. The 13M oscillator is programmable
2. Add 0.1ms if the wake up event is external
6.2.8
Idle-Mode Timing
Table 6-10. Idle-Mode Timing Specifications
Symbol
6.2.9
Description
—
13M mode to deep idle mode entry
—
1
—
μs
—
Deep idle mode exit to 13M mode
—
1
—
μs
—
Run mode to idle run mode entry
—
1
—
μs
—
Idle run mode exit to run mode
—
1
—
μs
Min
Typical
Max
Units
Frequency-Change Timing
Table 6-11. Frequency-Change Timing Specifications
Symbol
Description
—
Delay between MCR command to
frequency change sequence completion
—
1501
—
μs
—
Delay to change between turbo, halfturbo and run modes
—
12
—
μs
—
Delay to enter 13M mode from any Run
mode 3
—
1
—
μs
—
Delay to exit 13M mode to any Run mode
—
24
—
μs
NOTES:
1. Any change to the CCCR[2N or L] bits followed by a write to CLFCFG[F] to initiate a frequency change
sequence, results in a PLL restart
2. Changing between turbo, half-turbo and run modes does not require a PLL restart
3. Software can only change into 13M mode from any run mode
4. Assuming software uses the PLL early enable feature (CCCR[PLL_EARLY_EN] prior to a frequency
change sequence
Electrical, Mechanical, and Thermal Specification
6-9
Intel® PXA270 Processor
AC Timing Specifications
6.2.10
Voltage-Change Timing
The PWR I2C uses the regular I2C protocol. The PWR I2C is clocked at 40 kHz (160 kHz fastmode operation is supported). Software controls the time required for initiating the voltage change
sequence through completion. The voltage-change timing is a product of the number of commands
issued plus the number of software-programmed delays. Table 6-12 shows the timing of a 1 byte
command issued to the power manager IC.
Set the I2C programmable output ramp rate with a default/reset ramp rate of 10mV/μs (refer to
VCC_CORE ramp rate specification in the Electrical Section) to support VCC_CORE dynamic
voltage management.
Table 6-12. Voltage-Change Timing Specification for a 1-Byte Command
Symbol
—
Description
Min
Typical
Max
Units
—
18
—
cycles2
Delay between voltage change sequence
start1 to command received by PMIC
NOTES:
1. Write 1 to PWRMODE[VC]
2. 40 kHz cycles
6.3
GPIO Timing Specifications
Table 6-13 shows the general-purpose I/O (GPIO) AC timing specifications.
Table 6-13. GPIO Timing Specifications
Symbol
Parameter
Min
Max
Units
Notes
taGPIO1
Assertion time required to detect
GPIO edge
154
—
ns
run, idle, or sense power modes
taGPIOLP2
Assertion time required to detect
GPIO low-power edge
62.5
—
µs
standby, sleep, or deep-sleep
power modes
tdGPIO1
De-assertion time required to
detect GPIO edge
154
—
ns
run, idle, or sense power modes
tdGPIOLP2
De-assertion time required to
detect GPIO low-power edge
62.5
—
µs
standby, sleep, or deep-sleep
power modes
tdiGPIO3
Time required for a GPIO edge to
be detected internally
231
—
ns
run, idle, or sense power modes
tdiGPIOLP4
Time required for a GPIO lowpower edge to be detected
internally
93.75
—
µs
standby, sleep, or deep-sleep
power modes
NOTES:
1. Period equal to two 13-MHz cycles
2. Period equal to two 32-kHz cycles
3. Period equal to three 13-MHz cycles
4. Period equal to three 32-kHz cycles
Note 4 describes the complete timing for a standby, sleep, or deep-sleep wake up source to be asserted and detected internally
(2 cycles for assertion (note 2) and 1 additional cycle for detection).
6-10
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
AC Timing Specifications
6.4
Memory and Expansion-Card Timing Specifications
Interfaces with the following memories must observe the AC timing requirements given in the
following subsections:
•
•
•
•
•
•
•
Note:
Section 6.4.1, “Internal SRAM Read/Write Timing Specifications”
Section 6.4.2, “SDRAM Parameters and Timing Diagrams”
Section 6.4.3, “ROM Parameters and Timing Diagrams”
Section 6.4.4, “Flash Memory Parameters and Timing Diagrams”
Section 6.4.5, “SRAM Parameters and Timing Diagrams”
Section 6.4.6, “Variable-Latency I/O Parameters and Timing Diagrams”
Section 6.4.7, “Expansion-Card Interface Parameters and Timing Diagrams”
The diagrams in this section use the following conventions:
• Input signals to the processor are represented using dashed waveforms.
• Outputs and bidirectional signals are represented using solid waveforms.
• Fixed parameters are shown using double arrows in grey (black and white print) or green
(color print).
• Programmable parameters are shown using bold single arrows.
• The processor register that is used to change a specific timing is given in the corresponding
timing table.
6.4.1
Internal SRAM Read/Write Timing Specifications
Table 6-14. SRAM Read/Write AC Specification
6.4.2
Symbols
Parameters
MIN
TYP
MAX
Units
tsramRD
4-beat read transfer
—
9
—
system bus
clocks
tsramWR
4-beat write transfer
—
7
—
system bus
clocks
SDRAM Parameters and Timing Diagrams
Table 6-15 shows the timing parameters used in Figure 6-7. Also see Section 6.4.3 and Figure 6-11
for additional SDRAM bus tenure information. See Figure 6-10 for SDRAM fly-by bus tenures.
Electrical, Mechanical, and Thermal Specification
6-11
Intel® PXA270 Processor
AC Timing Specifications
Symbols
VCC_MEM =
2.5V +/- 10%4
VCC_MEM =
1.8V +20% / –5%3
Parameters
VCC_MEM =
3.3V +/- 10%5
MIN
TYP
MAX
MIN
TYP
MAX
MIN
TYP
MAX
Units
Notes
Table 6-15. SDRAM Interface AC Specifications (Sheet 1 of 2)
tsdCLK
SDCLK1, SDCLK2
period
9.6
—
76.9
9.6
—
76.9
9.6
—
76.9
ns
1,
2
tsdCMD
nSDCAS,
nSDRAS, nWE,
nSDCS assert time
1
—
1
1
—
1
1
—
1
SDCLK
—
tsdCAS
nSDCAS to
nSDCAS assert
time
2
—
—
2
—
—
2
—
—
SDCLK
—
tsdRCD
nSDRAS to
nSDCAS assert
time
1
MDCNFG
[DTCx]
3
1
MDCNFG
[DTCx]
3
1
MDCNFG
[DTCx]
3
SDCLK
6
tsdRP
nSDRAS Pre
charge
2
MDCNFG
[DTCx]
3
2
MDCNFG
[DTCx]
3
2
MDCNFG
[DTCx]
3
SDCLK
6
tsdCL
CAS Latency
2
MDCNFG
[DTCx]
3
2
MDCNFG
[DTCx]
3
2
MDCNFG
[DTCx]
3
SDCLK
6
tsdRAS
nSDRAS active
time
3
MDCNFG
[DTCx]
7
3
MDCNFG
[DTCx]
7
3
MDCNFG
[DTCx]
7
SDCLK
6
tsdRC
nSDRAS cycle
time
4
MDCNFG
[DTCx]
11
4
MDCNFG
[DTCx]
11
4
MDCNFG
[DTCx]
11
SDCLK
6
tsdWR
write recovery time
(time from last data
in the
PRECHARGE)
2
—
2
2
—
2
2
—
2
SDCLK
—
tsdSDOS
MA<24:10>,
MD<31:0>,
DQM<3:0>,
nSDCS<3:0>,
nSDRAS,
nSDCAS, nWE,
nOE, SDCKE1,
RDnWR output
setup time to
SDCLK<2:1> rise
2.5
—
—
2.5
—
2.5
—
—
ns
—
tsdSDOH
MA<24:10>,
MD<31:0>,
DQM<3:0>,
nSDCS<3:0>,
nSDRAS,
nSDCAS, nWE,
nOE, SDCKE1,
RDnWR output
hold time from
SDCLK<2:1> rise
1.5
—
—
1.5
—
1.5
—
—
ns
—
VCC_CORE = 0.85 V +/–
10%, with 1.71 V<=
VCC_MEM <= 3.63 V
6-12
VCC_CORE = 1.1 V +/–
10%, with 1.71 V <=
VCC_MEM <= 3.63 V
VCC_CORE = 1.3 V +/–
10%, with 1.71 V <=
VCC_MEM <= 3.63 V
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
AC Timing Specifications
Symbols
Parameters
VCC_MEM =
2.5V +/- 10%4
VCC_MEM =
1.8V +20% / –5%3
VCC_MEM =
3.3V +/- 10%5
MIN
TYP
MAX
MIN
TYP
MAX
MIN
TYP
MAX
Units
Notes
Table 6-15. SDRAM Interface AC Specifications (Sheet 2 of 2)
tsdSDIS
MD<31:0> read
data input setup
time from
SDCLK<2:1> rise
3.0
—
—
3.0
—
—
0.5
—
—
ns
—
tsdSDIH
MD<31:0> read
data input hold
time from
SDCLK<2:1> rise
2.0
—
—
2.0
—
—
1.8
—
—
ns
—
NOTES:
1. SDCLK for SDRAM slowest period is accomplished by divide-by-2 of the 26-MHz CLK_MEM. The fastest possible SDCLK is
accomplished by configuring CLK_MEM at 104 MHz and not setting MDREFR[KxDB2].
2. SDCLK1 and SDCLK2 frequencies are configured to be CLK_MEM frequency divided by 1 or 2, depending on the bit fields
MDREFR[K1DB2] and MDREFR[K2DB2] settings.
3. These numbers are for VCC_MEM = 1.8 V +20% / –5%, VOL = 0.4 V, and VOH = 1.4 V, with each applicable 4-bit field of the
system memory buffer strength registers (BSCNTRP and BSCNTRN) set to TBD (msb:lsb) and each applicable SDCLK<2:1>
divide-by-2 and divide-by-4 register bits MDREFR[KxDB2] clear.
4. These numbers are for VCC_MEM = 2.5 V +/– 10%, VOL = 0.4 V, and VOH = 2.1 V, with each applicable 4-bit field of the system
memory buffer strength registers (BSCNTRP and BSCNTRN) set to 0b1010 (msb:lsb) and each applicable SDCLK<2:1> divideby-2 and divide-by-4 register bit MDREFR[KxDB2] clear.
5. These numbers are for VCC_MEM = 3.3 V +/– 10%, VOL = 0.4 V, and VOH = 2.4 V, with each applicable 4-bit field of the system
memory buffer strength registers (BSCNTRP and BSCNTRN) set to 0b1010 (msb:lsb) and each applicable SDCLK<2:1> divideby-2 and divide-by-4 register bit MDREFR[KxDB2] clear.
6. Refer to the “Memory Controller” chapter in the Intel® PXA27x Processor Family Developer’s Manual for register configuration.
Electrical, Mechanical, and Thermal Specification
6-13
Intel® PXA270 Processor
AC Timing Specifications
Figure 6-7. SDRAM Timing
tsdCLK
SDCLK<1>
SDCKE<1>
tsdRC
tsdCL
tsdRP
tsdCMD
command nop act
nop
read
nop
tsdCMD
pre
nop
act
nop
write
nop
pre
nop
nSDCS<0>
tsdRAS
nSDRAS
tsdRCD
nSDCAS
nWE
tsdSDIS
tsdIH
MD<31:0> read
tsdSDOS
tsdSDOH
tWR
MD<31:0> write
DQM<3:0>
0b0000
0
1
2
3
mask data values
RDnWR
6-14
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
AC Timing Specifications
Figure 6-8. SDRAM 4-Beat Read/4-Beat Write, Different Banks Timing
SDCLK<1>
SDCKE<1>
command
read(0) pre(1)
nop
act(1)
nop
write(1)
nop
nSDCS<0>
nSDCS<1>
nSDRAS
nSDCAS
MA<24:10>
col
bank
row
col
nWE
MD<31:0> (read)
rd0_0
rd0_1 rd0_2 rd0_3
wd1_0 wd1_1 wd1_2 wd1_3
MD<31:0> (write)
DQM<3:0>
0b0000
0
1
2
3
mask data bytes
RDnWR
NOTES:
1. MDCNFG[DTC] = 0b00 (CL = 2, tRP = 2 clk, tRCD = 1 clk), MDCNFG[STACK] = 0b00
2. See the SDRAM timing diagram.
Electrical, Mechanical, and Thermal Specification
6-15
Intel® PXA270 Processor
AC Timing Specifications
Figure 6-9. SDRAM 4-Beat Write/4-Beat Write, Same Bank-Same Row Timing
SDCLK<1>
SDCKE<1>
command
nop
write(0)
nop
write(0)
nop
nSDCS<0>
nSDRAS
nSDCAS
MA<24:10>
col
col
nWE
MD<31:0>
wd0_0 wd0_1 wd0_2 wd0_3 wd0_4 wd0_5 wd0_6 wd0_7
DQM<3:0>
mask0
mask1 mask2 mask3 mask4 mask5 mask6 mask7
mask data bytes
RDnWR
NOTES:
1. MDCNFG[DTC] = 0b01 (CL = 2, tRP = 2 clks)
2. See the SDRAM timing diagram.
6-16
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
AC Timing Specifications
Figure 6-10. SDRAM Fly-by DMA Timing
latch data rd3
latch data rd2
latch data rd1
latch data rd0
SDCLK<1>
latch DVAL[1] asserted
drive data wd0
drive data wd1
drive data wd2
drive data wd3
SDCLK<2>
SDCKE<1>
command
read
pre
col
bank
nop
act
nop
write
nop
nSDCS<0>
nSDCS<2>
nSDRAS
nSDCAS
MA<24:10>
row
col
nWE
MD<31:0>
DQM<3:0>
rd0
rd1
rd2
rd3
wd0
wd1
wd2
wd3
mask0 mask1 mask2 mask3
0b0000
mask data bytes
RDnWR
DVAL<0>
DVAL<1>
Latch data on rising edge of SDCLK<1> when
DVAL<0> is asserted.
Using DVAL<1> driven two clocks early,
drive data on rising edge of SDCLK<2>.
NOTES: 1. MDCNFG[DTC] = 0b00 (CL = 2, tRP = 2 clk, tRCD = 1 clk)
2. See the SDRAM timing diagram.
6.4.3
ROM Parameters and Timing Diagrams
Table 6-16 lists the timings for ROM reads. See Figure 6-11, Figure 6-12, Figure 6-13, and
Figure 6-14 for timings diagrams representing burst and non-burst ROM reads.
Note:
Table 6-16 lists programmable register items. See the “Memory Controller” chapter in the Intel®
PXA27x Processor Family Developer’s Manual for register configurations for more information on
these items.
Table 6-16. ROM AC Specification (Sheet 1 of 2)
Symbols
Parameters
MIN
TYP
MAX
Units†
Notes
tromAS
Address setup to nCS assert
1
—
1
clk_mem
—
tromCES
nCS setup to nOE asserted
—
—
0
clk_mem
—
tromCEH
nCS hold from nOE de-asserted
—
—
0
clk_mem
—
tromDSOH
MD setup to address valid
1.5
—
—
clk_mem
—
Electrical, Mechanical, and Thermal Specification
6-17
Intel® PXA270 Processor
AC Timing Specifications
Table 6-16. ROM AC Specification (Sheet 2 of 2)
Symbols
Parameters
MIN
TYP
MAX
Units†
Notes
tromDOH
MD hold from address valid
0
—
—
clk_mem
—
tromAVDLF
Address valid to data latched for the
first read access
2
MSCx[RDF]+2
32
clk_mem
—
tromAVDLS
Address valid to data latched for
subsequent reads of non-burst
devices
1
MSCx[RDF]+1
31
clk_mem
—
tflashAVDVS
Address valid to data valid for
subsequent reads of burst devices
1
MSCx[RDN]+1
31
clk_mem
—
tromCD
nCS de-asserted after a read of next
nCS or nSDCS asserted (minimum)
1
MSCx[RRR]*2+
1
15
clk_mem
—
†
Numbers shown as integer multiples of the clk_mem period are ideal. Actual numbers vary with pin-to-pin differences in
loading and transition direction (rise or fall). For more information, refer to the “Memory Control” chapter in the Intel® PXA27x
Processor Family Developer’s Manual.
6-18
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
AC Timing Specifications
Figure 6-11. 32-Bit Non-burst ROM, SRAM, or Flash Read Timing
CLK_MEM
tromAS
nCS<0>
tromAVDLS
tromAVDLS
MA<25:2>
0
tromAVDLS
tromAVDLF
1
2
3
0b00
MA<1:0>(SA1110x='0')
0b00 / 0b01 / 0b10 / 0b11
MA<1:0>(SA1110x='1')
nADV(nSDCAS)
tromCES
tromCEH
nOE
nWE
RDnWR
tromDOH
tromDSOH
tromDOH
tromDSOH
tromDOH
tromDSOH
tromDOH
tromDSOH
MD<31:0>
0b00
DQM<3:0>(SA1110x='0')
DQM<3:0>(SA1110x='1')
corresponding mask value
tromCD
nCSx or nSDCSx
NOTE: MSC0[RDF0] = 4, MSC0[RRR0] = 1
Electrical, Mechanical, and Thermal Specification
6-19
Intel® PXA270 Processor
AC Timing Specifications
Figure 6-12. 32-Bit Burst-of-Eight ROM or Flash Read Timing
CLK_MEM
nCS<0>
tAS
MA<25:5>
MA<4:2>
0
tromAVDLF
tromAVDLS
1
2
3
4
5
6
7
0b00
MA<1:0>(SA1110x='0')
0b00 / 0b01 / 0b10 / 0b11
MA<1:0>(SA1110x='1')
nADV(nSDCAS)
tCES
tCEH
nOE
nWE
RDnWR
tDOH
tDSOH
MD<31:0>
DQM<3:0>(SA1110x='0')
DQM<3:0>(SA1110x='1')
0b0000
corresponding mask value
tromCD
nCSx or nSDCSx
NOTE: MSC0[RDF0] = 4, MSC0[RDN0] = 1, MSC0[RRR0] = 1
6-20
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
AC Timing Specifications
Figure 6-13. Eight-Beat Burst Read from 16-Bit Burst-of-Four ROM or Flash Timing
CLK_MEM
nCS<0>
tromAS
address
MA<25:4>
MA<3>
tromAVDLF
tromAVDLS
tromAVDLF
MA<2:1>
0
1
2
3
tromAVDLS
0
MA<0>(SA1110x='0')
0b0
MA<0>(SA1110x='1')
0b0 / 0b1
1
2
3
nADV(nSDCAS)
tromCES
tromCEH
nOE
nWE
RDnWR
tromDOH
tromDSOH
tromDOH
tromDSOH
MD<15:0>
0b00
DQM<1:0>(SA1110x='0')
0b00 or 0b10/0b01
DQM<1:0>(SA1110x='1')
tromCD
nCSx or nSDCSx
NOTE: MSC0[RDF0] = 4, MSC0[RDN0] = 1, MSC0[RRR0] = 0
Electrical, Mechanical, and Thermal Specification
6-21
Intel® PXA270 Processor
AC Timing Specifications
Figure 6-14. 16-bit ROM/Flash/SRAM Read for 4/2/1 Bytes Timing
CLK_MEM
tromCD
tromCD
tromCD
nCS<0>
MA<25:1>
tromAS
addr
addr + 1
tromAS
addr
tromAS
addr
tromAS
addr
addr + 1
MA<0>(SA1110x='0')
0
0
0
0
MA<0>(SA1110x='1')
0/1
0/1
0/1
0/1
nADV(nSDCAS)
tromAVDLF
tflashAVDVS
tromAVDLS
tromCES
tromCEH
tromAVDLF
tromCES
tromAVDLF
tromCES
tromAVDLF
tromCES
nOE
nWE
RDnWR
tromDSOH
tromDOH
tromDSOH
tromDOH
tromDOH
tromDOH
tromDSOH
tromDOH
tromDSOH
tromDOH
tromDSOH
tromDSOH
MD<15:0>
DQM<1:0>(SA1110x='0')
0b00
0b00
0b00
0b00
DQM<1:0>(SA1110x='1')
mask
mask
mask
mask
32-bit read
Applies to:
16-bit ROM or
non-burst flash
16-bit SRAM
16-bit read
8-bit read
32-bit Read
Applies to:
16-bit ROM or
non-burst flash
16-bit SRAM
16-bit burst flash
Applies to:
16-bit ROM or
non-burst flash
16-bit SRAM
16-bit burst flash
Applies to:
16-bit Burst Flash
NOTE: MSC0[RDF0] = 2, MSC0[RDN0] = 1, MSC0[RRR0] = 1
6.4.4
Flash Memory Parameters and Timing Diagrams
The following sections describe the read/write parameters and timing diagrams for asynchronous
and synchronous flash-memory interfaces with the memory controller.
6.4.4.1
Flash Memory Read Parameters and Timing Diagrams
Section 6.4.4.1.1 describes asynchronous flash reads. Section 6.4.4.1.2 describes synchronous
flash reads.
6.4.4.1.1
Asynchronous Flash Read Parameters and Timing Diagrams
The timings listed in Table 6-16 for ROM reads also apply to asynchronous flash reads. See
Figure 6-11, Figure 6-12, Figure 6-13, and Figure 6-14 for timings diagrams representative of an
asynchronous flash read.
6-22
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
AC Timing Specifications
6.4.4.1.2
Synchronous Flash Read Parameters and Timing Diagrams
Table 6-17 lists the timing parameters used in Figure 6-15, and, for stacked flash packages,
Figure 6-16.
Symbols
Parameters
MIN
TYP
MAX
MIN
Divide by 12
TYP
MAX
MIN
Divide by 23
TYP
MAX
Units
Notes
Table 6-17. Synchronous Flash Read AC Specifications (Sheet 1 of 2)
Divide by 44
9.6
—
38.5
19.
2
—
76.9
38.5
—
154
ns
1
MA<25:0> setup to
nSDCAS (as
nADV) asserted
1
—
1
1
—
2
1
—
4
CLK_MEM
—
tffCES
nCS setup to
nSDCAS (as
nADV) asserted
1
—
1
1
—
2
1
—
4
CLK_MEM
—
tffADV
nSDCAS (as
nADV) pulse width
1
—
1
3
—
3
7
—
7
CLK_MEM
—
52
CLK_MEM
5
tffCLK
SDCLK0 period
tffAS
tffOS
nSDCAS (as
nADV) de-assertion
to nOE assertion
FCC – 1
(for
FCC<5)
1
FCC – 2
13
2
(for
FCC>=5)
(FCC – 1)
*2
(for
FCC<5)
(FCC – 2)
*2
(for
FCC>=5)
26
7
(FCC * 4)
–7
(for
FCC<5)
(FCC – 2)
*4
(for
FCC>=5)
tffCEH
nOE de-assertion
to nCS deassertion
4
—
4
8
—
8
16
—
16
CLK_MEM
—
tffDS
CLK to data valid
2
FCC
15
2
FCC
15
2
FCC
15
CLK_MEM
5
VCC_MEM =
1.8V +20% / -5%6
VCC_MEM =
2.5V +/- 10%7
VCC_MEM =
3.3V +/- 10%8
tffSDOS
MA<25:0>,
MD<31:0>,
DQM<3:0>,
nCS<3:0>,
nSDCAS (nADV),
nWE, nOE,
RDnWR output
setup time to
SDCLK0 rise
8
—
—
8
—
—
8
—
—
ns
—
tffSDOH
MD<31:0>,
DQM<3:0>,
nCS<3:0>,
nSDCAS (nADV),
nWE, nOE,
RDnWR output
hold time from
SDCLK0 rise
4.5
—
—
4.5
—
—
4.5
—
—
ns
—
VCC_CORE = 0.85 V +/
– 10%, with 1.71 V<=
VCC_MEM <= 3.63 V
Electrical, Mechanical, and Thermal Specification
VCC_CORE = 1.1 V +/–
10%, with 1.71 V <=
VCC_MEM <= 3.63 V
VCC_CORE = 1.3 V +/–
10%, with 1.71 V <=
VCC_MEM <= 3.63 V
6-23
Intel® PXA270 Processor
AC Timing Specifications
Parameters
MIN
TYP
MAX
MIN
TYP
MAX
MIN
TYP
MAX
Units
Notes
Table 6-17. Synchronous Flash Read AC Specifications (Sheet 2 of 2)
tffSDIS
MD<31:0> read
data input setup
time from SDCLK0
rise
2.2
—
—
2.2
—
—
2.2
—
—
ns
—
tffSDIH
MD<31:0> read
data input hold time
from SDCLK0 rise
2.9
—
—
2.9
—
—
2.9
—
—
ns
—
Symbols
NOTES:
1. SDCLK0 may be configured to be CLK_MEM divided by 1, 2 or 4. SDCLK0 for synchronous flash memory can be at the slowest,
divide-by-4 of the 26-MHz CLK_MEM. The fastest possible SDCLK0 is accomplished by configuring CLK_MEM at 104 MHz and
clearing the MDREFR[K0DB2] or MDREFR[K0DB4] bit fields.
2. SDCLK0 frequency equals CLK_MEM frequency (MDREFR[K0DB4] and MDREFR[K0DB2] bit fields are clear)
3. SDCLK0 frequency equals CLK_MEM/2 frequency (MDREFR[K0DB2] is set and MDREFR[K0DB4] is clear).
4. SDCLK0 frequency equals CLK_MEM/4 frequency (MDREFR[K0DB4] is set).
5. Use SXCNFG[SXCLx] to configure the value for the frequency configuration code (FCC).
6. These numbers are for VCC_MEM = 1.8 V +20% / -5%, VOL = 0.4 V, and VOH = 1.4 V, with each applicable 4-bit field of the
system memory buffer strength registers (BSCN TRP and BSCNTRN) set to TBD (msb:lsb) and each applicable SDCLK0 divideby-2 and divide-by-4 register bits (MDREFR[K0DB2] and MDREFR[K0DB4]) clear. If MDREFR[K0DB2 is set, the corresponding
output setup and hold times are increased and decreased, respectively, by 0.25 times the SDCLK0 period.
7. These numbers are for VCC_MEM = 2.5 V +/– 10%, VOL = 0.4 V, and VOH = 2.1 V, with each applicable 4-bit field of the system
memory buffer strength registers (BSCNTRP and BSCNTRN) set to 0b1010 (msb:lsb) and each applicable SDCLK0 divide-by-2
and divide-by-4 register bit (MDREFR[K0DB2] and MDREFR[K0DB4]) clear. If MDREFR[K0DB2 is set, the corresponding output
setup and hold times are increased and decreased, respectively, by 0.25 times the SDCLK0 period.
8. These numbers are for VCC_MEM = 3.3 V +/– 10%, VOL = 0.4 V, and VOH = 2.4 V, with each applicable 4-bit field of the system
memory buffer strength registers (BSCNTRP and BSCNTRN) set to 0b1010 (msb:lsb) and each applicable SDCLK0 divide-by-2
and divide-by-4 register bit (MDREFR[K0DB2] and MDREFR[K0DB4]) clear. If MDREFR[K0DB2 is set, the corresponding output
setup and hold times are increased and decreased, respectively, by 0.25 times the SDCLK0 period.
6-24
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
AC Timing Specifications
Figure 6-15. Synchronous Flash Burst-of-Eight Read Timing
CLK_MEM
SDCLK<0>
MA<19:2>
0b00
MA<1:0>(SA1110x=0)
MA<1:0>(SA1110x=1)
0b00/0b01/0b10/0b11
nCS<0>
CODE
CODE+1
nADV(nSDCAS)
nOE
nWE
MD<31:0>
0b0000
DQM<3:0>(SA1110x=0)
DQM<3:0>(SA1110x=1)
corresponding mask value
NOTES: 1) SXCNFG[CL] = 0b100 (CL = 5, frequency code configuration = 4)
2) CODE = frequency configuration code
Electrical, Mechanical, and Thermal Specification
6-25
Intel® PXA270 Processor
AC Timing Specifications
Figure 6-16. Synchronous Flash Stacked Burst-of-Eight Read Timing
CLK_MEM
SDCLK<3>
MA<19:2>
0b00
MA<1:0>(SA1110x=0)
MA<1:0>(SA1110x=1)
0b00/0b01/0b10/0b11
nCS<0>
CODE
CODE+1
nADV(nSDCAS)
nOE
nWE
MD<31:0>
DQM<3:0>(SA1110x=0)
DQM<3:0>(SA1110x=1)
0b0000
corresponding mask value
NOTE: SXCNFG[CL] = 0b100 (CL = 5, frequency code configuration = 4)
SA1110CR[SXSTACK] = 0b01
6-26
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
AC Timing Specifications
Figure 6-17 indicates which clock data would be latched following the assertion of
nSDCAS(ADV), depending on the configuration of the SXCNFG[SXCLx] bit field. The period in
the diagram indicated by different frequency configuration codes (Fcodes or FCCs) is equal to the
number of SDCLK0 cycles between the READ command and the clock edge on which data is
driven onto the bus.
Figure 6-17. First-Access Latency Configuration Timing
SDCLK<0>
nCS<0>
Valid Address
MA<19:0>
nSDCAS
0b0000
DQM<3:0>
Code 2
Beat 0
MD (Code = 2)
Beat 1
Beat 2
Beat 3 Beat 4
Beat 5
Beat 0
Beat 1
Beat 2 Beat 3
Beat 4
Beat 1 Beat 2
Beat 3
Beat 0
Beat 1
Beat 2
Beat 0
Beat 1
Code 3
MD (Code = 3)
Code 4
Beat 0
MD (Code = 4)
Code 5
MD (Code = 5)
Code 6
MD (Code = 6)
Code 7
Beat 0
MD (Code = 7)
NOTE: CODE = Frequency Configuration Code
Electrical, Mechanical, and Thermal Specification
6-27
Intel® PXA270 Processor
AC Timing Specifications
The burst read example shown in Figure 6-18 represents waveforms that result when
SXCNFG[SXCLx] is configured as 0b0100, representing a frequency configuration code equal to
3. The following example can help determine the appropriate setting for SXCNFG[SXCLx].
Parameters defined by the processor:
• tffSDOH (max) = SDCLK<0> to CE# (nCE), ADV# (nADV), or address valid, whichever
occurs last
• tffSDIS (min) = Data setup to SDCLK<0>
Parameters defined by flash memory:
• tVLQV (min) = ADV# low to output delay
• tVLCH (min) = ADV# low to clock
• tCHQV (max) = SDCLK<0> to output valid
Use the following equations when calculating the frequency configuration code:
(1) SDCLK period = (1 / frequency)
(2) n (SDCLK period) ≥ tVLQV - tVLCH - tCHQV
(3) n = (tVLQV - tVLCH - tCHQV) / SDCLK period, where
n = frequency configuration code rounded up to integer value
(4) SDCLK period ≥ tCHQV + tffSDIS
Example
The timing information below is only an example. See Table 6-17 for actual synchronous AC
timings.
SDCLK<0> frequency = 50 MHz
tVLQV = 70 ns (typical timing from synchronous flash memory)
tVLCH = 10 ns (min)
tCHQV = 14 ns (min)
From Eq.(1):
1 / 50 (MHz) = 20 ns
From Eq.(2):
n(20 ns) ≥ 70 ns - 10 ns - 14 ns
n(20 ns) ≥ 46 ns
n = (46 / 20) ns = 2.3 ns
n = 3
Use Equation 4 to help verify the maximum possible frequency at which the synchronous flash
memory can run with the memory controller. The following example uses Equation 4:
SDCLK<0> frequency = 66 MHz
tCHQV = 11 ns (max)
tffSDIS = 3 ns (min)
From Eq. (1):
1 / 66 (MHz) = 15.15 ns
From Eq. (4):
15.15 ns ≥ 11 ns + 3 ns
15.15 ns ≥ 14 ns
The results from this example indicate that the 66-MHz memory works without problems with the
memory controller.
Note:
6-28
All AC timings must be considered to avoid timing violations in the memory-to-memory-controller
interface.
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
AC Timing Specifications
Figure 6-18. Synchronous Flash Burst Read Example
SDCLK<0>
tffSDOH
nCS<0>
tAVCH
tffSDOH
nSDCAS (ADV#)
tffSDOH
Valid Address
MA
tffSDIS
tCHQV
tVLQV
Beat 0
MD
6.4.4.2
Beat1
Flash Memory Write Parameters and Timing Diagrams
Table 6-18 lists the AC specification for both burst and non-burst flash writes shown in Figure 6-19
and, for stacked flash packages, Figure 6-20.
Table 6-18. Flash Memory AC Specification (Sheet 1 of 2)
Symbols
Parameters
MIN
TYP
MAX
Units1
Notes
tflashAS
Address setup to nCS assert
1
—
1
clk_mem
—
tflashAH
Address hold from nWE de-asserted
1
—
1
clk_mem
—
tflashASW
Address setup to nWE asserted
1
—
3
clk_mem
2
tflashCES
nCS setup to nWE asserted
2
—
2
clk_mem
—
tflashCEH
nCS hold from nWE de-asserted
1
—
1
clk_mem
—
tflashWL
nWE asserted time
1
MSCx[RDF]+1
31
clk_mem
—
tflashDSWH
MD/DQM setup to nWE de-asserted
2
MSCx[RDF]+2
32
clk_mem
—
tflashDH
MD/DQM hold from nWE deasserted
1
—
1
clk_mem
—
tflashDSOH
MD setup to address valid
1.5
—
—
clk_mem
—
Electrical, Mechanical, and Thermal Specification
6-29
Intel® PXA270 Processor
AC Timing Specifications
Table 6-18. Flash Memory AC Specification (Sheet 2 of 2)
Symbols
Parameters
MIN
TYP
MAX
Units1
Notes
tflashDOH
MD hold from address valid
0
—
—
clk_mem
—
tflashCD
nCS de-asserted after a read/write to
next nCS or nSDCS asserted
(minimum)
1
MSCx[RRR]*2 +
1
15
clk_mem
—
NOTES:
1. Numbers shown as integer multiples of the CLK_MEM period are ideal. Actual numbers vary with pin-to-pin differences in
loading and transition direction (rise or fall).
2. On the first data beat of burst transfer, the tflashASW is 3 CLK_MEM periods. On subsequent data beats, the tflashASW is 1
CLK_MEM period.
Figure 6-19. 32-Bit Flash Write Timing
CLK_MEM
tflashCD
nCS<0>
MA<25:2>
tflashAS
command address
tflashAS
data address
0b00
0b00
MA<1:0>
tflashASW
tflashASW
tflashCEH
tflashCEH
tflashCES
tflashCES
tflashAH
tflashWL
tflashAH
tflashWL
tflashDH
tflashDSWH
tflashDH
tflashDSWH
nWE
nOE
RDnWR
MD<31:0>
CMD
DATA
DQM<3:0>
0b0000
0b0000
nADV(nSDCAS)
tflashCD
nCSx or nSDCSx
First Bus Cycle
Second Bus Cycle
NOTE: MSC0[RDF0] = 2, MSC0[RRR0] = 2
6-30
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
AC Timing Specifications
Figure 6-20. 32-Bit Stacked Flash Write Timing
CLK_MEM
tflashCD
nWE
MA<25:2>
tflashAS
command address
tflashAS
data address
0b00
MA<1:0>
0b00
tflashASW
tflashASW
tflashCEH
tflashCEH
tflashCES
tflashCES
tflashAH
tflashWL
tflashAH
tflashWL
tflashDH
tflashDSWH
tflashDH
tflashDSWH
nCS<0> or nCS<1>
nOE
RDnWR
MD<31:0>
CMD
DATA
DQM<3:0>
0b0000
0b0000
nADV(nSDCAS)
tflashCD
nCSx
First Bus Cycle
Second Bus Cycle
* MSC0[RDF0] = 2, MSC0[RRR0] = 2, SA1110{SXSTACK] = 00
Electrical, Mechanical, and Thermal Specification
6-31
Intel® PXA270 Processor
AC Timing Specifications
Figure 6-21. 16-Bit Flash Write Timing
CLK_MEM
nCS<2>
tflashAS
MA<25:1>
addr
MA<0>
0b0
tflashCEH
tflashCES
tflashWL
nWE
nOE
RDnWR
tflashDH
tflashDSWH
MD<15:0>
Bytes 1:0
DQM<1:0>
0b00
nADV(nSDCAS)
tflashCD
nCSx or nSDCSx
Applies to:
16-bit Non-Burst Flash
16-bit Burst Flash
NOTE: MSC1[RDN2] = 2, MSC1[RDF2] = 1, MSC1[RRR2] = 2
6.4.5
SRAM Parameters and Timing Diagrams
The following sections describe the read/write parameters and timing diagrams for SRAM
interfaces with the memory controller.
6.4.5.1
SRAM Read Parameters and Timing Diagrams
The timing for a read access is identical to that for a non-burst ROM read (see Figure 6-11). The
timings listed in Table 6-16 for ROM reads are also used for SRAM reads. See Figure 6-11 and
Figure 6-14 for timings diagrams representing 16-bit SRAM transferring four, two, and one byte(s)
during read-bus tenures.
6.4.5.2
SRAM Write Parameters and Timing Diagrams
Figure 6-22 and Figure 6-23 show the timing for 32-bit and 16-bit SRAM writes. Table 6-19 lists
the timings used in Figure 6-22 and Figure 6-23.
6-32
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
AC Timing Specifications
During writes, data pins are actively driven by the processor and are not three-stated, regardless of
the states of the individual DQM signals. For SRAM writes, the DQM signals are used as byte
enables.
Note:
Table 6-19 lists programmable register items. See the “Memory Controller”chapter in the Intel®
PXA27x Processor Family Developer’s Manual for register configurations for more information on
these items.
Table 6-19. SRAM Write AC Specification
MIN
TYP
MAX
Units1
Notes
Address setup to nCS assert
1
—
1
clk_mem
—
tsramAH
Address hold from nWE de-asserted
1
—
1
clk_mem
—
tsramASW
Address setup to nWE asserted
1
—
3
clk_mem
2
tsramCES
nCS setup to nWE asserted
2
—
2
clk_mem
—
tsramCEH
nCS hold from nWE de-asserted
1
—
1
clk_mem
—
tsramWL
nWE asserted time
1
MSCx[RDN]+1
31
clk_mem
—
tsramDSWH
MD/DQM setup to nWE de-asserted
2
MSCx[RDN]+2
32
clk_mem
—
tsramDH
MD/DQM hold from nWE deasserted
1
—
1
clk_mem
—
tramCD
nCS de-asserted after a read to next
nCS or nSDCS asserted (minimum)
1
MSCx[RRR]*2+
1
15
clk_mem
—
Symbols
Parameters
tsramAS
NOTES:
1. Numbers shown as integer multiples of the CLK_MEM period are ideal. Actual numbers vary with pin-to-pin differences in
loading and transition direction (rise or fall).
2. On the first data beat of burst transfer, the tsramASW is 3 CLK_MEM periods. On subsequent data beats, the tsramASW is 1
CLK_MEM period.
Electrical, Mechanical, and Thermal Specification
6-33
Intel® PXA270 Processor
AC Timing Specifications
Figure 6-22. 32-Bit SRAM Write Timing
CLK_MEM
nCS<0>
MA<25:2>
MA<1:0>
tsramAS
0
byte addr
1
2
3
byte addr
byte addr
byte addr
tsramASW
tsramCEHW
tsramCESW
tsramASW
tsramAH
tsramWL
tsramWL
tsramAH
tsramWL
tsramWL
nWE
nOE
RDnWR
tsramDH
tsramDSWH
tsramDOH
D1
MD<31:0>
D0
DQM<3:0>
mask0
mask1
D2
D3
mask2
mask3
tsramCD
nCSx or nSDCSx
nADV(nSDCAS)
NOTE: 4-Beat burst, MSC0[RDN0] = 2, MSC0[RRR0] = 1
6-34
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
AC Timing Specifications
Figure 6-23. 16-bit SRAM Write for 4/2/1 Byte(s) Timing
CLK_MEM
tsramCD
tsramCD
nCS<2>
tramAS
addr
MA<25:1>
'0'
MA<0>
tramAS
addr
addr+1
'0'
tramAS
addr
'0'
tsramWL
tsramASW
tsramAH
tsramCES
tsramCEH
tsramWL
tsramWL
'0' or '1'
tsramCEH
tsramCES
tsramCEH
tsramCES
tsramWL
tsramWL
nWE
nOE
RDnWR
tsramDH
tsramDH
tsramDH
tsramDH
tsramDSWH
tsramDSWH
MD<15:0>
tsramDSWH
Bytes 1:0 Bytes 3:2
Bytes 1:0
Byte 0 OR 1
tsramDSWH
DQM<1:0>
0b00
0b00
0b01 / 0b10
nADV(nSDCAS)
tsramCD
nCSx or nSDCSx
32-bit Write
16-bit Write
8-bit Write
NOTE: MSC1[RDF2]=1, MSC1[RDN]=2, MSC1[RRR2]=2
6.4.6
Variable-Latency I/O Parameters and Timing Diagrams
The following sections describe the read/write parameters and timing diagrams for VLIO memory
interfaces with the memory controller.
Table 6-20 lists the timing-information references for both the read and the write timing diagrams.
Note:
Table 6-20 lists programmable register items. For more information on these items, see the
“Memory Controller” chapter in the Intel® PXA27x Processor Family Developer’s Manual for
register configurations.
Electrical, Mechanical, and Thermal Specification
6-35
Intel® PXA270 Processor
AC Timing Specifications
Table 6-20. VLIO Timing
MIN
TYP
MAX2
Units1
Notes
Address setup to nCS asserted
1
—
1
clk_mem
—
tvlioAH
Address hold from nPWE/nOE deasserted
2
MSCx[RDN]
30
clk_mem
—
tvlioASRW0
Address setup to nPWE/nOE
asserted (1st access)
3
—
3
clk_mem
—
tvlioASRWn
Address setup to nPWE/nOE
asserted (next access(es))
2
MSCx[RDN]
30
clk_mem
—
tvlioCES
nCS setup to nPWE/nOE asserted
2
—
2
clk_mem
—
tvlioCEH
nCS hold from nPWE/nOE deasserted
1
—
1
clk_mem
—
tvlioDSWH
MD/DQM setup (minimum) to nPWE
de-asserted
5
MSCx[RDF]+2
32
clk_mem
—
tvlioDH
MD/DQM hold from nPWE deasserted
2
MSCx[RDN]
30
clk_mem
—
tvlioDSOH
MD setup to address changing
1.5
—
clk_mem
—
tvlioDOH
MD hold from address changing
0
—
ns
—
tvlioRDYH
RDY hold from nPWE/nOE deasserted
0
—
—
ns
—
tvlioRWA
nPWE/nOE assert period between
writes
4
MSC[RDF]+1 +
Waits
31 +
Waits
clk_mem
—
tvlioRWD
nPWE/nOE de-asserted period
between writes
4
MSCx[RDN*2]
60
clk_mem
3
tvlioCD
nCS de-asserted after a read/write to
next nCS or nSDCS asserted
(minimum)
1
MSCx[RRR]*2 +
1
15
clk_mem
—
Symbols
Parameters
tvlioAS
NOTES:
1. Numbers shown as integer multiples of the CLK_MEM period are ideal. Actual numbers vary with pin-to-pin differences in
loading and transition direction (rise or fall).
2. Maximum values reflect the register dynamic ranges.
3. Depending on the programmed value of MSC[RDN] and the clk_mem speed, this can be a significant amount of time.
Processor does not drive the data bus during this time between transfers. If the VLIO does not drive the data bus during this
time between transfers, the data bus is not driven for this period of time. If MSC[RDN] is programmed to 60 (which equals 60
CLK_MEM cycles), then the data bus could potentially not be driven for 30*2 = 60 CLK_MEM cycles.
6.4.6.1
Variable Latency I/O Read Timing
Figure 6-24 shows the timing for 32-bit variable-latency I/O (VLIO) memory reads. Table 6-20
lists the timing parameters used in these diagrams.
6-36
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
AC Timing Specifications
Figure 6-24. 32-Bit VLIO Read Timing
CLK_MEM
nCS<0>
MA<25:2>
tvlioAS
addr
addr + 1
addr + 3
0b00
MA<1:0>(SA1110x='0')
MA<1:0>(SA1110x='1')
tvlioASRW0
0b00/0b01/0b10/0b11
tvlioASRWn
tvlioASRWn
tvlioAH
0 Waits
tvlioAH
1 Wait
tvlioCES
nOE
addr + 2
tvlioASRWn
tvlioAH
2 Waits
tvlioRWA
tvlioRWD
tvlioRWD
3 Waits
tvlioRWA
tvlioRWD
tvlioAH
tvlioCEH
tvlioRWA
nPWE
RDnWR
tvlioRDYH
tvlioRDYH
tvlioRDYH
tvlioRDYH
RDY
RDY_sync
tvlioDOH
tvlioDSOH
tvlioDOH
tvlioDSOH
tvlioDOH
tvlioDSOH
tvlioDSOH
tvlioDOH
MD<31:0>
DQM<3:0>(SA1110x='0')
0b0000
DQM<3:0>(SA1110x='1')
corresponding mask value
tvlioCD
nCSx or nSDCSx
NOTE: MSC0[RDF0] = 3, MSC0[RDN0 = 2, MSC0[RRR0] = 1
6.4.6.2
Variable-Latency I/O Write Timing
Figure 6-25 shows the timing for 32-bit VLIO memory writes. Table 6-20 list the timing
parameters used in Figure 6-25.
Electrical, Mechanical, and Thermal Specification
6-37
Intel® PXA270 Processor
AC Timing Specifications
Figure 6-25. 32-Bit VLIO Write Timing
CLK_MEM
nCS<0>
MA<25:2>
tvlioAS
addr
addr + 1
addr + 2
addr + 3
tvlioASRWn
tvlioASRWn
0b00
MA<1:0>
tvlioASRW0
tvlioASRWn
tvlioAH
tvlioAH
tvlioCES
0 Waits
tvlioAH
1 Wait
tvlioRWD
tvlioRWA
tvlioAH
2 Waits
tvlioRWA
tvlioRWD
3 Waits
tvlioRWA
tvlioRWD
tvlioCEH
tvlioRWA
nPWE
nOE
RDnWR
tvlioRDYH
tvlioRDYH
tvlioRDYH
tvlioRDYH
RDY
RDY_sync
MD<31:0>
D0
DQM<3:0>
mask0
tvlioDH
tvlioDSWH
tvlioDSWH
D1
mask1
tvlioDH
tvlioDSWH
D2
mask2
tvlioDH
tvlioDH
tvlioDSWH
D3
mask3
tvlioCD
nCSx or nSDCSx
NOTE: MSC0[RDF0] = 3, MSC0[RDN0] = 2, MSC0[RRR0] = 1
6-38
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
AC Timing Specifications
6.4.7
Expansion-Card Interface Parameters and Timing Diagrams
The following sections describe the read/write parameters and timing diagrams for CompactFlash*
and PC Card* (expansion card) memory interfaces with the memory controller.
Table 6-21 shows the timing parameters used in the timing diagrams, Figure 6-26 and Figure 6-27.
Note:
Table 6-21 lists programmable register items. See the “Memory Controller” chapter in the Intel®
PXA27x Processor Family Developer’s Manual for register configurations for more information on
these items.
Table 6-21. Expansion-Card Interface AC Specifications
Symbols
Parameters
MIN
TYP
MAX
Units
Notes
tcdAVCL
Address Valid to CMD Low
2
MCx[SET]
127
CLK_MEM
1,2,3,4
tcdCHAI
CMD High to Address Invalid
0
MCx[HOLD]
63
CLK_MEM
1,2,3,5
tcdDVCL
Write Data Valid to CMD Low
—
1
—
CLK_MEM
1,3
tcdCHWDI
CMD High to Write Data Invalid
—
4
—
CLK_MEM
1,3
tcdDVCH
Read Data Valid to CMD High
2
—
—
CLK_MEM
1,3
tcdCHRDI
CMD High to Read Data Invalid
0
—
—
ns
3
tcdCMD
CMD Assert During Transfers
—
tcdCLPS +
tcdPHCH +
nPWAIT
assertion
—
CLK_MEM
1,3
tcdILCL
nIOIS16 Low to CMD Low
4
—
—
CLK_MEM
1,3
tcdCHIH
CMD High to nIOIS16 High
2
—
—
CLK_MEM
1,3
tcdCLPS
CMD Low to nPWAIT Sample
—
x_ASST_WAIT
—
CLK_MEM
1,3,6,7
tcdPHCH
nPWAIT High to CMD High
—
x_ASST_HOLD
—
CLK_MEM
1,3,6,8
NOTES:
1. All numbers shown are ideal, integer multiples of the CLK_MEM period. Actual numbers vary with pin-to-pin differences in
loading and transition direction (rise or fall).
2. Includes signals MA[25:0], nPREG, and nPSKTSEL.
3. CMD refers to signals nPWE, nPOE, nPIOW, and nPIOR
4. Refer to the Intel® PXA27x Processor Family Developer’s Manual, Expansion Memory Timing Configuration registers to
change the assertion of CMD using the MCx[SET] bit fields.
5. Refer to the Intel® PXA27x Processor Family Developer’s Manual, Expansion Memory Timing Configuration registers to
increase the assertion of CMD using the MCx[HOLD] bit fields.
6. Refer to the Intel® PXA27x Processor Family Developer’s Manual, Expansion Memory Timing Configuration registers to
increase timings. The timings are changed by programming the MCx[ASST] respective bit fields. Refer to the PC Card
Interface Command Assertion Code table to see the effect of MCx[ASST].
7. tcdCLPS equals CLK_MEM * x_ASST_WAIT. Refer to the PC Card Interface Command Assertion Code table in the Intel®
PXA27x Processor Family Developer’s Manual for the correlation between x_ASST_WAIT and the MCx[ASST] bit field.
8. tcdPHCH equals CLK_MEM * x_ASST_HOLD. Refer to the PC Card Interface Command Assertion Code table in the Intel®
PXA27x Processor Family Developer’s Manual for the correlation between x_ASST_HOLD and the MCx[ASST] bit field.
Electrical, Mechanical, and Thermal Specification
6-39
Intel® PXA270 Processor
AC Timing Specifications
Figure 6-26. Expansion-Card Memory or I/O 16-Bit Access Timing
Read Data Latch
CLK_MEM
nPCE[2],nPCE[1]
tcdCHAI
MA[25:0],nPREG,PSKTSEL
tcdCLPS
tcdPHCH
tcdAVCL
tcdCMD
nPWE,nPOE,nPIOW,nPIOR
tcdILCL
tcdCHIH
nIOIS16
tcdDVCL
tcdCHWDI
MD[15:0] (write)
RDnWR
nPWAIT
tcdDVCH
tcdCHRDI
MD[15:0] (read)
6-40
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
AC Timing Specifications
Figure 6-27. Expansion-Card Memory or I/O 16-Bit Access to 8-Bit Device Timing
Read Data Latch
Read Data Latch
CLK_MEM
MA<25:1>,nPREG,PSKTSEL
MA<0>
nPCE<2>
nPCE<1>
tcdAVCL
tcdAVCL
tcdCMD
tcdCHAI
tcdCMD
tcdCHAI
nPIOW (or) nPIOR
RDnWR
tcdILCL
tcdCHIH
nIOIS16
tcdPHCH
tcdPHCH
tcdCLPS
tcdCLPS
nPWAIT
tcdDVCH
tcdDVCH
tcdCHRDI
tcdCHRDI
MD<7:0> (read)
tcdCHWDI
MD<7:0> (write)
tcdDVCL
Low Byte
Electrical, Mechanical, and Thermal Specification
tcdCHWDI
High Byte
6-41
Intel® PXA270 Processor
AC Timing Specifications
6.5
LCD Timing Specifications
Figure 6-28 describes the LCD timing parameters. The LCD pin timing specifications are
referenced to the pixel clock (L_PCLK_WR). Table 6-22 gives the values for the parameters.
Figure 6-28. LCD Timing Definitions
LCCR3[PCP] = 1
L_PCLK_WR
tpclkdv
L_LDD
tpclklv
L_LCLK_A0
L_BIAS
tpclkfv
L_FCLK_RD
tpclkbv
LCCR3[PCP] = 0
L_PCLK_WR
tpclkdv
L_LDD
tpclklv
L_LCLK_A0
L_BIAS
tpclkfv
tpclkbv
L_FCLK_RD
Table 6-22. LCD Timing Specifications (Sheet 1 of 2)
6-42
Symbol
Description
Min
Max
Units
Notes
Tpclkdv
L_PCLK_WR rise/fall to L_LDD<17:0>
driven valid
—
7
ns
1
Tpclklv
L_PCLK_WR fall to L_LCLK_A0 driven
valid
—
7
ns
2
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
AC Timing Specifications
Table 6-22. LCD Timing Specifications (Sheet 2 of 2)
Symbol
Description
Min
Max
Units
Notes
Tpclkfv
L_PCLK_WR fall to L_FCLK_RD driven
valid
—
7
ns
2
Tpclkbv
L_PCLK_WR rise to L_BIAS driven valid
—
14
ns
2
NOTES:
1. The LCD data pins can be programmed to be driven on either the rising or falling edge of the pixel clock
(L_PCLK_WR).
2. These LCD signals can toggle when L_PCLK_WR is not clocking (between frames). At this time, they are
clocked with the internal version of the pixel clock before it is driven out onto the L_PCLK_WR pin.
Electrical, Mechanical, and Thermal Specification
6-43
Intel® PXA270 Processor
AC Timing Specifications
6.6
SSP Timing Specifications
Figure 6-29 describes the SSP timing parameters. The SSP pin timing specifications are referenced
to SSPCLK. Table 6-23 gives the values for the parameters.
Note:
In Figure 6-29, read the term “tSFMV” as “TSTXV.”
Figure 6-29. SSP Master Mode Timing Definitions
SSPSCLK
Tsfmv
SSPSFRM
Tsfmv
SSPTXD
Trxds
Trxdh
SSPRXD
Table 6-23. SSP Master Mode Timing Specifications
Symbol
Description
Min
Max
Units
Tsfmv
SSPSCLK rise to SSPSFRM driven valid
Trxds
SSPRXD valid to SSPSCLK fall (input setup)
11
21
ns
ns
Trxdh
SSPSCLK fall to SSPRXD invalid (input hold)
0
ns
Tsfmv
SSPSCLK rise to SSPTXD valid
22
Notes
ns
Figure 6-30. Timing Diagram for SSP Slave Mode Transmitting Data to an External Peripheral
PXA27x processor transmitting data
PXA27x SSP (Slave Mode) transmitting data to external peripheral
SSPSCLK
(from Peripheral)
tSCLK2TXD_output_delay
SSPSFRM
(from Peripheral)
tSFRM2TXD_output_delay
SSPTXD
(from SSP)
6-44
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
AC Timing Specifications
Table 6-24. Timing Specification SSP Slave Mode Transmitting Data to External Peripheral
Parameter
Description
Min
Typ
Max
Units
tSFRM2TXD_output_delay
Frame to TX Data Out
10.58
ns
tSCLK2TXD_output_delay
Clock to Tx Data Out
10.52
ns
Figure 6-31. Timing Diagram for SSP Slave Mode Receiving Data from External Peripheral
PXA27 processor receiving data
PXA27x SSP (Slave Mode receiving data from external peripheral
tSCLK_input_delay
SSPSCLK
(from Peripheral)
Data Capture
SSPSFRM
(from Peripheral)
tSFRM_input_delay
SSPRXD
(from Peripheral)
Data Capture
tRXD_input_delay
Table 6-25. Timing Specification for SSP Slave Mode Receiving Data from External Peripheral
Parameter
6.7
Description
Min
Typical
Max
Units
tSFRM_input_delay
Frame to Rx Data Capture
5.21
ns
tSCLK_input_delay
Clock to Rx Data Capture
5.04
ns
tRXD_input_delay
Rx Data Setup to Capture
4.81
ns
JTAG Boundary Scan Timing Specifications
Table 6-26 shows the AC specifications for the JTAG boundary-scan test signals. Figure 6-32
shows the timing diagram.
Table 6-26. Boundary Scan Timing Specifications (Sheet 1 of 2)
Symbol
Parameter
Min
Max
Units
Notes
TBSF
TCK Frequency
0.0
33.33
MHz
TBSCH
TCK High Time
15.0
—
ns
Measured at 1.5 V
TBSCL
TCK Low Time
15.0
—
ns
Measured at 1.5 V
TBSCR
TCK Rise Time
—
5.0
ns
0.8 V to 2.0 V
TBSCF
TCK Fall Time
—
5.0
ns
2.0 V to 0.8 V
Electrical, Mechanical, and Thermal Specification
—
6-45
Intel® PXA270 Processor
AC Timing Specifications
Table 6-26. Boundary Scan Timing Specifications (Sheet 2 of 2)
Symbol
Parameter
Min
Max
Units
Notes
TBSIS1
Input Setup to TCK TDI, TMS
4.0
—
ns
—
TBSIH1
Input Hold from TCK TDI, TMS
6.0
—
ns
—
TBSIS2
Input Setup to TCK nTRST
25.0
—
ns
—
TBSIH2
Input Hold from TCK nTRST
3.0
—
ns
—
TnTRST
Assertion time of nTRST
6
—
ms
—
TBSOV1
TDO Valid Delay
1.5
6.9
ns
Relative to falling edge of TCK
TOF1
TDO Float Delay
1.1
5.4
ns
Relative to falling edge of TCK
Figure 6-32. JTAG Boundary-Scan Timing
TBSF
TBSCH
TBSCL
TCK
TBSIS2
TBSIH2
TBSIS1
TBSIH1
TnTRST
nTRST
TMS
TBSIS1
TBSIH1
TDI
TBSOV1
TBSOV1
TBSOV1
TBSOV1
TOF1
TBSOV1
TBSOV1
TBSOV1
TDO
6-46
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Shift-IR
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Run-Test/Idle
Te
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Te
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og
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S e - T et
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Controller State
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
AC Timing Specifications
6.8
Intel® Quick Capture Interface AC Timing
Table 6-27 lists the timing parameters used in Figure 6-33.
Table 6-27. Intel® Quick Capture AC Timing Specification
Symbol
Description
Min
Typical
Max
Units
tciIS
Camera Interface Setup Time
5
—
—
ns
tciIH
Camera Interface Hold Time
5
—
—
ns
Figure 6-33. Intel® Quick Capture Interface Timing
tciIS tciIH
CIF_PCLK*
CIF_DD
* CIF_PCLK Data Sampling edge determined by the CICR 4[PCP] setting
Electrical, Mechanical, and Thermal Specification
6-47
Intel® PXA270 Processor
AC Timing Specifications
6.9
MultiMediaCard Timing Specifications
Figure 6-34. MultiMedia Card timing Diagrams
tWH
tWL
tFREQ
MMCLK
tISU
MMDAT0/1
tIH
Data In
Invalid
Data In
tOSU
MMDAT2/3
Data Out
Invalid
tOH
Data Out
Table 6-28. MultiMedia Card timing specifications
Symbol
Parameter
Min
Max
Unit
tFREQ
MMCLK Frequency Data Transfer
Mode
0
19.5
MHz
tFREQ
MMCLK Frequency Identification
Mode
0
400
KHz
tWH
Clock high time
10
—
ns
tWL
Clock low time
10
—
ns
trise
Clock rise time
—
10
ns
1
tfall
Clock fall time
—
10
ns
1
tISU
Data input setup time
3
—
ns
tIH
Data input hold time
3
—
ns
tOSU
Output data setup time
13.1
—
ns
tOH
Output data hold time
9.7
—
ns
Notes
NOTE:
3. Rise and fall times measured from 10% - 90% of voltage level.
6.10
tWH
Clock high time
10
—
ns
tWL
Clock low time
10
—
ns
trise
Clock rise time
—
10
ns
1
tfall
Clock fall time
—
10
ns
1
Secure Digital (SD/SDIO) Timing
Figure 6-35 and Table 6-29 define the Secure Digital (SD/SDIO) controller AC timing
specifications.
6-48
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
AC Timing Specifications
Figure 6-35. SD/SDIO timing diagrams
tFREQ
tWL
tWH
MMCLK
tISU
MMDAT0/1
tIH
Data In
Invalid
td(ID)
MMDAT2/3
td(Q)
Invalid
Data Out
Table 6-29. SD/SDIO Timing Specifications
Symbol
Parameter
Min
Max
Unit
tFREQ
MMCLK Frequency Data Transfer
Mode
0
19.5
MHz
tFREQ
MMCLK Frequency Identification
Mode
01/100
400
KHz
Notes
tWH
Clock high time
50
—
ns
tWL
Clock low time
50
—
ns
trise
Clock rise time
—
10
ns
2
tfall
Clock fall time
—
10
ns
2
tISU
Data input setup time
5
—
ns
tIH
Data input hold time
5
—
ns
td(Q)
Output Delay time during Data
Transfer Mode
0
14
ns
td(ID)
Output Delay time during
Identification Mode
0
50
ns
NOTES:
1. 0 KHz is when the clock is stopped. The minimum 100 KHz frequency range is where
continuous clock is required.
2. Rise and fall times measured from 10% - 90% of voltage level.
§§
Electrical, Mechanical, and Thermal Specification
6-49
Intel® PXA270 Processor
AC Timing Specifications
6-50
Electrical, Mechanical, and Thermal Specification
Glossary
3G: An industry term used to describe the next, still-to-come generation of wireless applications. It represents a
move from circuit-switched communications (where a device user has to dial in to a network) to broadband,
high-speed, packet-based wireless networks (which are always on). The first generation of wireless
communications relied on analog technology, followed by digital wireless communications. The third generation
expands the digital capabilities by including high-speed connections and increased reliability.
802.11: Wireless specifications developed by the IEEE, outlining the means to manage packet traffic over a
network and ensure that packets do not collide, which could result in the loss of data, when travelling from device
to device.
8PSK: 8 phase shift key modulation scheme. Used in the EDGE standard.
AC ’97 AC-link standard serial interface for modem and audio
ACK: Handshake packet indicating a positive acknowledgment.
Active device: A device that is powered and is not in the suspended state.
Air interface: the RF interface between a mobile cellular handset and the base station
AMPS: Advanced Mobile Phone Service. A term used for analog technologies, the first generation of wireless
technologies.
Analog: Radio signals that are converted into a format that allows them to carry data. Cellular phones and other
wireless devices use analog in geographic areas with insufficient digital networks.
ARM* V5te: An ARM* architecture designation indicating the processor is conforms to ARM* architecture
version 5, including “Thumb” mode and the “El Segundo” DSP extensions.
Asynchronous Data: Data transferred at irregular intervals with relaxed latency requirements.
Asynchronous RA: The incoming data rate, Fs i, and the outgoing data rate, Fs o, of the RA process are
independent (i.e., there is no shared master clock). See also rate adaptation.
Asynchronous SRC: The incoming sample rate, Fsi, and outgoing sample rate, Fso, of the SRC process are
independent (i.e., there is no shared master clock). See also sample rate conversion.
Audio device: A device that sources or sinks sampled analog data.
AWG#: The measurement of a wire’s cross-section, as defined by the American Wire Gauge standard.
Babble: Unexpected bus activity that persists beyond a specified point in a (micro)frame.
Backlight Inverter: A device to drive cold cathode fluorescent lamps used to illuminate LCD panels.
Bandwidth: The amount of data transmitted per unit of time, typically bits per second (b/s) or bytes per second
(B/s). The size of a network “pipe” or channel for communications in wired networks. In wireless, it refers to the
range of available frequencies that carry a signal.
Base Station:The telephone company’s interface to the Mobile Station
Electrical, Mechanical, and Thermal Specification
Glossary-1
Intel® PXA270 Processor
Glossary
BGA: Ball Grid Array
BFSK: binary frequency shift keying. A coding scheme for digital data.
Bit: A unit of information used by digital computers. Represents the smallest piece of addressable memory within a
computer. A bit expresses the choice between two possibilities and is typically represented by a logical one (1) or
zero (0).
Bit Stuffing: Insertion of a “0” bit into a data stream to cause an electrical transition on the data wires, allowing a
PLL to remain locked.
Blackberry: A two-way wireless device (pager) made by Research In Motion (RIM) that allows users to check
e-mail and voice mail translated into text, as well as page other users of a wireless network service. It has a
miniature “qwerty” keyboard that can be used by your thumbs, and uses SMS protocol. A Blackberry user must
subscribe to the proprietary wireless service that allows for data transmission.
Bluetooth: A short-range wireless specification that allows for radio connections between devices within a 30-foot
range of each other. The name comes from 10th-century Danish King Harald Blatand (Bluetooth), who unified
Denmark and Norway.
BPSK: binary phase shift keying. A means of encoding digital data into a signal using phase-modulated
communications.
b/s: Transmission rate expressed in bits per second.
B/s: Transmission rate expressed in bytes per second.
BTB: Branch Target Buffer
BTS: Base Transmitter Station
Buffer: Storage used to compensate for a difference in data rates or time of occurrence of events, when transmitting
data from one device to another.
Bulk Transfer: One of the four USB transfer types. Bulk transfers are non-periodic, large bursty communication
typically used for a transfer that can use any available bandwidth and can also be delayed until bandwidth is
available. See also transfer type.
Bus Enumeration: Detecting and identifying USB devices.
Byte: A data element that is eight bits in size.
Capabilities: Those attributes of a USB device that are administrated by the host.
CAS: Cycle Accurate Simulator
CAS-B4-RAS: See CBR.
CBR: CAS Before RAS. Column Address Strobe Before Row Address Strobe. A fast refresh technique in which
the DRAM keeps track of the next row it needs to refresh, thus simplifying what a system would have to do to
refresh the part.
CDMA: Code Division Multiple Access U.S. wireless carriers Sprint PCD and Verizon use CDMA to allocate
bandwidth for users of digital wireless devices. CDMA distinguishes between multiple transmissions carried
simultaneously on a single wireless signal. It carries the transmissions on that signal, freeing network room for the
Glossary-2
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Glossary
wireless carrier and providing interference-free calls for the user. Several versions of the standard are still under
development. CDMA should increase network capacity for wireless carriers and improve the quality of wireless
messaging. CDMA is an alternative to GSM.
CDPD: Cellular Digital Packet Data Telecommunications companies can use DCPD to transfer data on unused
cellular networks to other users. IF one section, or “cell” of the network is overtaxed, DCPD automatically allows
for the reallocation of services.
Cellular: Technology that senses analog or digital transmissions from transmitters that have areas of coverage
called cells. As a user of a cellular phone moves between transmitters from one cell to another, the users’ call
travels from transmitter to transmitter uninterrupted.
Circuit Switched: Used by wireless carriers, this method lets a user connect to a network or the Internet by dialing
in, such as with a traditional phone line. Circuit switched connections are typically slower and less reliable than
packet-switched networks, but are currently the primary method of network access for wireless users in the U.S.
CF: Compact Flash memory and I/O card interface
Characteristics: Those qualities of a USB device that are unchangeable; for example, the device class is a device
characteristic.
Client: Software resident on the host that interacts with the USB System Software to arrange data transfer between
a function and the host. The client is often the data provider and consumer for transferred data.
CML: Current mode logic
Configuring Software: Software resident on the host software that is responsible for configuring a USB device.
This may be a system configuration or software specific to the device.
Control Endpoint: A pair of device endpoints with the same endpoint number that are used by a control pipe.
Control endpoints transfer data in both directions and, therefore, use both endpoint directions of a device address
and endpoint number combination. Thus, each control endpoint consumes two endpoint addresses.
Control Pipe: Same as a message pipe.
Control Transfer: One of the four USB transfer types. Control transfers support configuration/command/status
type communications between client and function. See also transfer type.
CRC: See Cyclic Redundancy Check.
CSP: Chip Scale Package.
CTE: Coefficient of thermal expansion
CTI: Computer Telephony Integration.
Cyclic Redundancy Check (CRC): A check performed on data to see if an error has occurred in transmitting,
reading, or writing the data. The result of a CRC is typically stored or transmitted with the checked data. The stored
or transmitted result is compared to a CRC calculated for the data to determine if an error has occurred.
D-cache: Data cache
DECT: the Digital European Cordless Telecommunications standard
Default Address: An address defined by the USB Specification and used by a USB device when it is first powered
or reset. The default address is 00H.
Electrical, Mechanical, and Thermal Specification
Glossary-3
Intel® PXA270 Processor
Glossary
Default Pipe: The message pipe created by the USB System Software to pass control and status information
between the host and a USB device’s endpoint zero.
Device: A logical or physical entity that performs a function. The actual entity described depends on the context of
the reference. At the lowest level, “device” may refer to a single hardware component, as in a memory device. At a
higher level, it may refer to a collection of hardware components that perform a particular function, such as a USB
interface device. At an even higher level, device may refer to the function performed by an entity attached to the
USB; for example, a data/FAX modem device. Devices may be physical, electrical, addressable, and logical. When
used as a non-specific reference, a USB device is either a hub or a function.
Device Address: A seven-bit value representing the address of a device on the USB. The device address is the
default address (00H) when the USB device is first powered or the device is reset. Devices are assigned a unique
device address by the USB System Software.
Device Endpoint: A uniquely addressable portion of a USB device that is the source or sink of information in a
communication flow between the host and device. See also endpoint address.
Device Resources: Resources provided by USB devices, such as buffer space and endpoints. See also Host
Resources and Universal Serial Bus Resources.
Device Software: Software that is responsible for using a USB device. This software may or may not also be
responsible for configuring the device for use.
DMA: Direct Memory Access
Downstream: The direction of data flow from the host or away from the host. A downstream port is the port on a
hub electrically farthest from the host that generates downstream data traffic from the hub. Downstream ports
receive upstream data traffic.
DQPSK: Differential Quadrature Phase Shift Keying a modulation technique used in TDMA.
Driver: When referring to hardware, an I/O pad that drives an external load. When referring to software, a program
responsible for interfacing to a hardware device, that is, a device driver.
DSP: Digital Signal Processing
DSTN Passive LCD Panel.
Dual band mobile phone: A phone that supports both analog and digital technologies by picking up analog signals
when digital signals fade. Most mobile phones are not dual-band.
DWORD: Double word. A data element that is two words (i.e., four bytes or 32 bits) in size.
Dynamic Insertion and Removal: The ability to attach and remove devices while the host is in operation.
E2PROM: See Electrically Erasable Programmable Read Only Memory.
EAV: End of active video
EDGE: Enhanced Data GSM Environment. A faster version of the GSM standard. It is faster because it can carry
messages using broadband networks that employ more bandwidth than standard GSM networks.
EEPROM: See Electrically Erasable Programmable Read Only Memory.
Electrically Erasable Programmable Read Only Memory (EEPROM): Non-volatile re-writable memory
storage technology.
Glossary-4
Electrical, Mechanical, and Thermal Specification
Intel® PXA270 Processor
Glossary
End User: The user of a host.
Endpoint: See device endpoint.
Endpoint Address: The combination of an endpoint number and an endpoint direction on a USB device. Each
endpoint address supports data transfer in one direction.
Endpoint Direction: The direction of data transfer on the USB. The direction can be either IN or OUT. IN refers to
transfers to the host; OUT refers to transfers from the host.
Endpoint Number: A four-bit value between 0H and FH, inclusive, associated with an endpoint on a USB device.
Envelope detector: An electronic circuit inside a USB device that monitors the USB data lines and detects certain
voltage related signal characteristics.
EOF: End-of-(micro)Frame.
EOP: End-of-Packet.
EOTD: Enhanced Observed Time Difference
ETM: Embedded Trace Macrocell, the ARM* real-time trace capability
External Port: See port.
Eye pattern: A representation of USB signaling that provides minimum and maximum voltage levels as well as
signal jitter.
FAR: Fault Address Register, part of the ARM* architecture.
False EOP: A spurious, usually noise-induced event that is interpreted by a packet receiver as an EOP.
FDD: The Mobile Station transmits on one frequency; the Base Station transmits on another frequency
FDM: Frequency Division Multiplexing. Each Mobile station transmits on a different frequency (within a cell).
FDMA: Frequency Division Multiple Access. An analog standard that lets multiple users access a group of radio
frequency bands and eliminates interference of message traffic.
FHSS: See Frequency Hopping Spread Spectrum.
FIQ: Fast Interrupt Request. See Interrupt Request.
Frame: A 1 millisecond time base established on full-/low-speed buses.
Frame Pattern: A sequence of frames that exhibit a repeating pattern in the number of samples transmitted per
frame. For a 44.1 kHz audio transfer, the frame pattern could be nine frames containing 44 samples followed by one
frame containing 45 samples.
Frequency Hopping Spread Spectrum: A method by which a carrier spreads out packets of information (voice or
data) over different frequencies. For example, a phone call is carried on several different frequencies so that when
one frequency is lost another picks up the call without breaking the connection.
Fs: See sample rate.
FSR: Fault Status Register, part of the ARM* architecture.
Electrical, Mechanical, and Thermal Specification
Glossary-5
Intel® PXA270 Processor
Glossary
Full-duplex: Computer data transmission occurring in both directions simultaneously.
Full-speed: USB operation at 12 Mb/s. See also low-speed and high-speed.
Function: A USB device that provides a capability to the host, such as an ISDN connection, a digital microphone,
or speakers.
GMSK: Gaussian Minimum Shift Keying. A modulation scheme used in GSM.
GPRS: General Packet Radio Service A technology that sends packets of data across a wireless network at speeds
up to 114 Kbps. Unlike circuit-switched networks, wireless users do not have to dial in to networks to download
information; GPRS wireless devices are “always on” in that they can send and receive data without dial-ins. GPRS
works with GSM.
GPS: Global Positioning Systems
GSM: Global System for Mobile Communications. A standard for how data is coded and transferred through the
wireless spectrum. The European wireless standard, also used in parts of Asia, GSM is an alternative to CDMA.
GSM digitizes and compresses data and sends it across a channel with two other streams of user data. GSM is based
on TDMA technology.
Hamming Distance: The distance (number of bits) between encoded values that can change without causing a
decode into the wrong value.
Handshake Packet: A packet that acknowledges or rejects a specific condition. For examples, see ACK and NAK.
HDML: Handheld Device Markup Language. HDML uses hypertext transfer protocol (HTTP) to display text
versions of web pages on wireless devices. Unlike WML, HDML is not based on XML. HDML does not allow
scripts, while WML uses a variant of JavaScript. Web site developers using HDML must re-code their web pages in
HDML to be viewed on the smaller screen sizes of handheld devices.
HARP: Windows CE standard development platform spec (Hardware Adaptation Reference Platform)
High-bandwidth endpoint: A high-speed device endpoint that transfers more than 1024 bytes and less than 3073
bytes per microframe.
High-speed: USB operation at 480 Mb/s. See also low-speed and full-speed.
Host :The host computer system where the USB Host controller is installed. This includes the host hardware
platform (CPU, bus, and so forth.) and the operating system in use.
Host Controller: The host’s USB interface.
Host Controller Driver (HCD): The USB software layer that abstracts the Host controller hardware. The Host
controller driver provides an SPI for interaction with a Host controller. The Host controller driver hides the
specifics of the Host controller hardware implementation.
Host Resources: Resources provided by the host, such as buffer space and interrupts. See also Device Resources
and Universal Serial Bus Resources.
HSTL: High-speed transceiver logic
Hub: A USB device that provides additional connections to the USB.
Hub Tier: One plus the number of USB links in a communication path between the host and a function.
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IMMU: Instruction Memory Management Unit, part of the Intel XScale® core.
I-Mode: A Japanese wireless service for transferring packet-based data to handheld devices created by NTT
DoCoMo. I-Mode is based on a compact version of HTML and does not currently use WAP.
I-cache: Instruction cache
IBIS: I/O Buffer Information Specification is a behavioral description of the I/O buffers and package
characteristics of a semiconductor device. IBIS models use a standard format to make it easier to import data into
circuit simulation software packages.
iDEN: Integrated Digital Enhanced Network. A technology that allows users to access phone calls, two-way radio
transmissions, paging and data transmissions from one wireless device. iDEN was developed by Motorola and
based on TDMA.
Interrupt Request (IRQ): A hardware signal that allows a device to request attention from a host. The host
typically invokes an interrupt service routine to handle the condition that caused the request.
Interrupt Transfer: One of the four USB transfer types. Interrupt transfer characteristics are small data,
non-periodic, low-frequency, and bounded-latency. Interrupt transfers are typically used to handle service needs.
See also transfer type.
I/O Request Packet: An identifiable request by a software client to move data between itself (on the host) and an
endpoint of a device in an appropriate direction.
IrDA: Infrared Development Association
IRP: See I/O Request Packet.
IRQ: See Interrupt Request.
ISI: Inter-signal interference. Data ghosting caused when multi-path delay causes previous symbols to interfere
with the one currently being processed.
ISM: Industrial, Scientific, and Medical band. Part of the wireless spectrum that is less regulated, such as 802.11.
Isochronous Data: A stream of data whose timing is implied by its delivery rate.
Isochronous Device: An entity with isochronous endpoints, as defined in the USB Specification, that sources or
sinks sampled analog streams or synchronous data streams.
Isochronous Sink Endpoint : An endpoint that is capable of consuming an isochronous data stream that is sent by
the host.
Isochronous Source Endpoint: An endpoint that is capable of producing an isochronous data stream and sending
it to the host.
Isochronous Transfer: One of the four USB transfer types. Isochronous transfers are used when working with
isochronous data. Isochronous transfers provide periodic, continuous communication between host and device. See
also transfer type.
Jitter: A tendency toward lack of synchronization caused by mechanical or electrical changes. More specifically,
the phase shift of digital pulses over a transmission medium.
kb/s: Transmission rate expressed in kilobits per second. A measurement of bandwidth in the U.S.
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kB/s: Transmission rate expressed in kilobytes per second.
Little endian: Method of storing data that places the least significant byte of multiple-byte values at lower storage
addresses. For example, a 16-bit integer stored in little endian format places the least significant byte at the lower
address and the most significant byte at the next address.
LOA: Loss of bus activity characterized by an SOP without a corresponding EOP.
Low-speed: USB operation at 1.5 Mb/s. See also full-speed and high-speed.
LSb: Least significant bit.
LSB: Least significant byte.
LVDS: Low-voltage differential signal
MAC: Multiply Accumulate unit
Mb/s: Transmission rate expressed in megabits per second.
MB/s: Transmission rate expressed in megabytes per second.
MC: Media Center. A combination digital set-top box, video and music jukebox, personal video recorder and an
Internet gateway and firewall that hooks up to a broadband connection.
Message Pipe: A bidirectional pipe that transfers data using a request/data/status paradigm. The data has an
imposed structure that allows requests to be reliably identified and communicated.
Microframe: A 125 microsecond time base established on high-speed buses.
MMC: Multimedia Card - small form factor memory and I/O card
MMX Technology: The Intel® MMX™ technology comprises a set of instructions that are designed to greatly
enhance the performance of advanced media and communications applications. See chapter 10 of the Intel®
Architecture Software Developers Manual, Volume 3: System Programming Guide, Order #245472.
Mobile Station: Cellular Telephone handset
M-PSK: multilevel phase shift keying. A convention for encoding digital data in which there are multiple states.
MMU: Memory Management Unit, part of the Intel XScale® core.
MSb: Most significant bit.
MSB: Most significant byte.
MSL: Mobile Scalable Link.
NAK: Handshake packet indicating a negative acknowledgment.
Non Return to Zero Invert (NRZI): A method of encoding serial data in which ones and zeroes are represented by
opposite and alternating high and low voltages where there is no return to zero (reference) voltage between encoded
bits. Eliminates the need for clock pulses.
NRZI: See Non Return to Zero Invert.
Object: Host software or data structure representing a USB entity.
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OFDM: See Orthogonal Frequency Division Multiplexing.
Orthogonal Frequency Division Multiplexing: A special form of multi-carrier modulation. In a multi-path
channel, most conventional modulation techniques are sensitive to inter-symbol interference unless the channel
symbol rate is small compared to the delay spread of the channel. OFDM is significantly less sensitive to
inter-symbol interference, because a special set of signals is used to build the composite transmitted signal. The
basic idea is that each bit occupies a frequency-time window that ensures little or no distortion of the waveform. In
practice, it means that bits are transmitted in parallel over a number of frequency-nonselective channels.
Packet: A bundle of data organized in a group for transmission. Packets typically contain three elements: control
information (for example, source, destination, and length), the data to be transferred, and error detection and
correction bits. Packet data is the basis for packet-switched networks, which eliminate the need to dial-in to send or
receive information, because they are “always on.”
Packet Buffer: The logical buffer used by a USB device for sending or receiving a single packet. This determines
the maximum packet size the device can send or receive.
Packet ID (PID): A field in a USB packet that indicates the type of packet, and by inference, the format of the
packet and the type of error detection applied to the packet.
Packet Switched Network: Networks that transfer packets of data.
PCMCIA: Personal Computer Memory Card Interface Association (PC Card)
PCS: Personal Communications services. An alternative to cellular, PCD works like cellular technology because it
sends calls from transmitter to transmitter as a caller moves. But PCS uses its own network, not a cellular network,
and offers fewer “blind spots” than cellular, where calls are not available. PCS transmitters are generally closer
together than their cellular counterparts.
PDA: Personal Digital Assistant. A mobile handheld device that gives users access to text-based information. Users
can synchronize their PDAs with a PC or network; some models support wireless communication to retrieve and
send e-mail and get information from the Internet.
Phase: A token, data, or handshake packet. A transaction has three phases.
Phase Locked Loop (PLL): A circuit that acts as a phase detector to keep an oscillator in phase with an incoming
frequency.
Physical Device: A device that has a physical implementation; for example, speakers, microphones, and CD
players.
PID: See Packet ID or Process ID.
PIO: Programmed input/output
Pipe: A logical abstraction representing the association between an endpoint on a device and software on the host.
A pipe has several attributes; for example, a pipe may transfer data as streams (stream pipe) or messages (message
pipe). See also stream pipe and message pipe.
PLL: See Phase Locked Loop.
PM: Phase Modulation.
Polling: Asking multiple devices, one at a time, if they have any data to transmit.
POR: See Power On Reset.
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Port: Point of access to or from a system or circuit. For the USB, the point where a USB device is attached.
Power On Reset (POR): Restoring a storage device, register, or memory to a predetermined state when power is
applied.
Process ID: Process identifier
Programmable Data Rate: Either a fixed data rate (single-frequency endpoints), a limited number of data rates
(32 kHz, 44.1 kHz, 48 kHz, …), or a continuously programmable data rate. The exact programming capabilities of
an endpoint must be reported in the appropriate class-specific endpoint descriptors.
Protocol: A specific set of rules, procedures, or conventions relating to format and timing of data transmission
between two devices.
PSP: Programmable Serial Protocol
PWM: Pulse Width Modulator
QBS: Qualification By Similarity. A technique allowed by JEDEC for part qualification when target parameters are
fully understood and data exist to warrant omitting a specific test.
QAM: quadrature amplitude modulation. A coding scheme for digital data.
QPSK: quadrature phase shift keying. A convention for encoding digital data into a signal using phase-modulated
communications.
RA: See rate adaptation.
Radio Frequency Device: These devices use radio frequencies to transmit data. One typical use is for bar code
scanning of products in a warehouse or distribution center, and sending that information to an ERP database.
Rate Adaptation: The process by which an incoming data stream, sampled at Fs i, is converted to an outgoing data
stream, sampled at Fs o, with a certain loss of quality, determined by the rate adaptation algorithm. Error control
mechanisms are required for the process. Fs i and Fs o can be different and asynchronous. Fs i is the input data rate
of the RA; Fs o is the output data rate of the RA.
Request: A request made to a USB device contained within the data portion of a SETUP packet.
Retire: The action of completing service for a transfer and notifying the appropriate software client of the
completion.
RGBT: Red, Green, Blue, Transparency
ROM: Read Only Memory.
Root Hub: A USB hub directly attached to the Host controller. This hub (tier 1) is attached to the host.
Root Port: The downstream port on a Root Hub.
RTC: Real-Time Clock
SA-1110: StrongARM* based applications processor for handheld products
Intel® StrongARM* SA-1111: Companion chip for the Intel® SA-1110 processor
SAD: Sum of absolute differences
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Sample: The smallest unit of data on which an endpoint operates; a property of an endpoint.
Sample Rate (Fs): The number of samples per second, expressed in Hertz (Hz).
Sample Rate Conversion (SRC): A dedicated implementation of the RA process for use on sampled analog data
streams. The error control mechanism is replaced by interpolating techniques. Service A procedure provided by a
System Programming Interface (SPI).
Satellite Phone: Phones that connect callers by satellite. Users have a world-wide alternative to terrestrial
connections. Typical use is for isolated users, such as crews of deep-see oil rigs with phones configured to connect
to a satellite service.
SAV: Start of active video
SAW: Surface Acoustic Wave filter
SDRAM: Synchronous Dynamic Random Access Memory.
Service Interval: The period between consecutive requests to a USB endpoint to send or receive data.
Service Jitter: The deviation of service delivery from its scheduled delivery time.
Service Rate: The number of services to a given endpoint per unit time.
SIMD: Single Instruction Multiple Data (a parallel processing architecture).
Smart Phone: A combination of a mobile phone and a PDA, which allow users to communicate as well as perform
tasks; such as, accessing the Internet and storing contacts in a database. Smart phones have a PDA-like screen.
SMROM: Synchronous Mask ROM
SMS: Short Messaging Service. A service through which users can send text-based messages from one device to
another. The message can be up to 160 characters and appears on the screen of the receiving device. SMS works
with GSM networks.
SOC: System On Chip
SOF: See Start-of-Frame.
SOP: Start-of-Packet.
SPI: See System Programming Interface. Also, “Serial Peripheral Interface protocol.
SPI: Serial Peripheral Interface
Split transaction: A transaction type supported by host controllers and hubs. This transaction type allows full- and
low-speed devices to be attached to hubs operating at high-speed.
Spread Spectrum: An encoding technique patented by actress Hedy Lamarr and composer George Antheil, which
broadcasts a signal over a range of frequencies.
SRAM: Static Random Access Memory.
SRC: See Sample Rate Conversion.
SSE: Streaming SIMD Extensions
Electrical, Mechanical, and Thermal Specification
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SSE2: Streaming SIMD Extensions 2: for Intel Architecture machines, 144 new instructions, a 128-bit SIMD
integer arithmetic and 128-bit SIMD double precision floating point instructions, enabling enhanced multimedia
experiences.
SSP: Synchronous Serial Port
SSTL: Stub series terminated logic
Stage: One part of the sequence composing a control transfer; stages include the Setup stage, the Data stage, and
the Status stage.
Start-of-Frame (SOF): The first transaction in each (micro)frame. An SOF allows endpoints to identify the start of
the (micro)frame and synchronize internal endpoint clocks to the host.
Stream Pipe: A pipe that transfers data as a stream of samples with no defined USB structure
SWI: Software interrupt.
Synchronization Type: A classification that characterizes an isochronous endpoint’s capability to connect to other
isochronous endpoints.
Synchronous RA: The incoming data rate, Fsi, and the outgoing data rate, Fso, of the RA process are derived from
the same master clock. There is a fixed relation between Fsi and Fso.
Synchronous SRC: The incoming sample rate, Fsi, and outgoing sample rate, Fso, of the SRC process are derived
from the same master clock. There is a fixed relation between Fsi and Fso.
System Programming Interface (SPI): A defined interface to services provided by system software.
TC: Temperature Cycling
TDD: Time Division Duplexing The Mobile Station and the Base Station transmit on same frequency at different
times.
TDM: See Time Division Multiplexing.
TDMA: Time Division Multiple Access. TDMA protocol allows multiple users to access a single radio frequency
by allocating time slots for use to multiple voice or data calls. TDMA breaks down data transmissions, such as a
phone conversation, into fragments and transmits each fragment in a short burst, assigning each fragment a time
slot. With a cell phone, the caller would not detect this fragmentation. TDMA works with GSM and digital cellular
services.
TDR: See Time Domain Reflectometer.
Termination: Passive components attached at the end of cables to prevent signals from being reflected or echoed.
TFT: Thin Film Twist, a type of active LCD panel.
Three-state: a high-impedance state in which the output is floating and is electrically isolated from the buffer's
circuitry.
Time Division Multiplexing (TDM): A method of transmitting multiple signals (data, voice, and/or video)
simultaneously over one communications medium by interleaving a piece of each signal one after another.
Time Domain Reflectometer (TDR): An instrument capable of measuring impedance characteristics of the USB
signal lines.
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Time-out: The detection of a lack of bus activity for some predetermined interval.
Token Packet: A type of packet that identifies what transaction is to be performed on the bus.
TPV: Third Party Vendor
Transaction: The delivery of service to an endpoint; consists of a token packet, optional data packet, and optional
handshake packet. Specific packets are allowed/required based on the transaction type.
Transaction translator: A functional component of a USB hub. The Transaction Translator responds to special
high-speed transactions and translates them to full/low-speed transactions with full/low-speed devices attached on
downstream facing ports.
Transfer: One or more bus transactions to move information between a software client and its function.
Transfer Type: Determines the characteristics of the data flow between a software client and its function. Four
standard transfer types are defined: control, interrupt, bulk, and isochronous.
TS: Thermal Shock
Turn-around Time: The time a device needs to wait to begin transmitting a packet after a packet has been received
to prevent collisions on the USB. This time is based on the length and propagation delay characteristics of the cable
and the location of the transmitting device in relation to other devices on the USB.
UART: Universal Asynchronous Receiver/Transmitter serial port
Universal Serial Bus Driver (USBD): The host resident software entity responsible for providing common
services to clients that are manipulating one or more functions on one or more Host controllers.
Universal Serial Bus Resources: Resources provided by the USB, such as bandwidth and power. See also Device
Resources and Host Resources.
Upstream: The direction of data flow towards the host. An upstream port is the port on a device electrically closest
to the host that generates upstream data traffic from the hub. Upstream ports receive downstream data traffic.
USBD: See Universal Serial Bus Driver.
USB-IF: USB Implementers Forum, Inc. is a nonprofit corporation formed to facilitate the development of USB
compliant products and promote the technology.
VBI: Vertical Blanking Interval, also known as the “backporch”.
Virtual Device: A device that is represented by a software interface layer. An example of a virtual device is a hard
disk with its associated device driver and client software that makes it able to reproduce an audio.WAV file.
VLIO: Variable Latency Input/Output interface.
YUV: A method of characterizing video signals typically used in digital cameras and PAL television specifying
luminance and chrominance.
WAP: Wireless Application Protocol. WAP is a set of protocols that lets users of mobile phones and other digital
wireless devices access Internet content, check voice mail and e-mail, receive text of faxes and conduct
transactions. WAP works with multiple standards, including CDMA and GSM. Not all mobile devices support
WAP.
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W-CDMA: Wideband CDMA, a third generation wireless technology under development that allows for
high-speed, high-quality data transmission. Derived from CDMA, W-CDMA digitizes and transmits wireless data
over a broad range of frequencies. It requires more bandwidth than CDMA, but offers faster transmission because it
optimizes the use of multiple wireless signals, instead of one, as does CDMA.
Wireless LAN: A wireless LAN uses radio frequency technology to transmit network messages through the air for
relatively short distances, like across an office building or a college campus. A wireless LAN can serve as a
replacement for, or an extension to, a traditional wired LAN.
Wireless Spectrum: A band of frequencies where wireless signals travel carrying voice and data information.
Word: A data element that is four bytes (32 bits) in size.
WML: Wireless Markup Language, a version of HDML is based on XML. Wireless applications developers use
WML to re-target content for wireless devices.
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