STMICROELECTRONICS STPC0366BTC3

STPC CONSUMER

PC Compatible Embeded Microprocessor
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POWERFUL X86 PROCESSOR
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64-BIT BUS ARCHITECTURE
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64-BIT DRAM CONTROLLER
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SVGA GRAPHICS CONTROLLER
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UMA ARCHITECTURE
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VIDEO SCALER
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DIGITAL PAL/NTSC ENCODER
VIDEO INPUT PORT
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CRT CONTROLLER
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135MHz RAMDAC
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3 LINE FLICKER FILTER
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SCAN CONVERTER
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PCI MASTER / SLAVE / ARBITER CTRL
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ISA MASTER/SLAVE INTERFACE
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IDE CONTROLLER
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DMA CONTROLLER
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INTERRUPT CONTROLLER
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TIMER / COUNTERS
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POWER MANAGEMENT
PBGA388
Figure 1. Logic Diagram
ISA BUS
x86
Core
Host I/F
STPC CONSUMER OVERVIEW
The STPC Consumer integrates a standard 5th
generation x86 core, a DRAM controller, a graphics subsystem, a video pipeline and support logic
including PCI, ISA and IDE controllers to provide a
single Consumer orientated PC compatible subsystem on a single device.
The device is based on a tightly coupled Unified
Memory Architecture (UMA), sharing the same
memory array between the CPU main memory
and the graphics and video frame buffers.
Extra facilities are implemented to handle video
streams. Features include smooth scaling and
color space conversion of the video input stream
and mixing with graphics data. The chip also includes a built-in digital TV encoder and anti-flicker
filters that allow stable, high-quality display on
standard PAL or NTSC television sets without additional components.
The STPC Consumer is packaged in a 388 Plastic
Ball Grid Array (PBGA).
8/2/00
ISA
m/s
IPC
PCI
m/s
EIDE
EIDE
PCI BUS
PCI
m/s
CCIR Input
VIP
TV Output
D igital
PAL/
NTSC
AntiFlicker
C olor Space
C onverter
Video
pipeline
2D
SVGA
CRTC
DRAM
CTRL
Color
Key
Chroma
Key
Monitor
H W C ursor
SYNC Output
1/51
Issue 1.2
STPC CONSUMER
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X86 Processor core
Fully static 32-bit 5-stage pipeline, x86
processor fully PC compatible.
Can access up to 4GBytes of external
memory.
8KByte unified instruction and data cache
with write back and write through capability.
Parallel processing integral floating point unit,
with automatic power down.
Clock core speeds up to of 100 MHz.
Fully static design for dynamic clock control.
Low power and system management modes.
Optimized design for 3.3V operation.
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DRAM Controller
Integrated system memory and graphic frame
memory.
Supports up to 128 MBytes system memory
in 4 banks and down to as little as 2Mbytes.
Supports 4MB, 8MB, 16MB, 32MB singlesided and double-sided DRAM SIMMs.
Four quad-word write buffers for CPU to
DRAM and PCI to DRAM cycles.
Four 4-word read buffers for PCI masters.
Supports Fast Page Mode & EDO DRAM.
Programmable timing for DRAM parameters
including CAS pulse width, CAS pre-charge
time and RAS to CAS delay.
60, 70, 80 & 100ns DRAM speeds.
Memory hole between 1 MByte & 8 MByte
supported for PCI/ISA busses.
Hidden refresh.
To check if your memory device is supported by
the STPC, please refer to Table 9-3 in the
Programming Manual.
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Graphics Engine
64-bit windows accelerator.
Backward compatibility to SVGA standards.
Hardware acceleration for text, bitblts,
transparent blts and fills.
Up to 64 x 64 bit graphics hardware cursor.
Up to 4MB long linear frame buffer.
8-, 16-, and 24-bit pixels.
Drivers for Windows and other operating
systems.
2/51
Issue 1.2
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VGA Controller
Integrated 135MHz triple RAMDAC allowing
for 1280 x 1024 x 75Hz display.
Requires external frequency synthesizer and
reference sources.
8-, 16-, 24-bit pixels.
Interlaced or non-interlaced output.
Video Input port
Accepts video inputs in CCIR 601/656 or
ITU-R 601/656, and stream decoding.
Optional 2:1 decimator
Stores captured video in off setting area of
the onboard frame buffer.
Video pass through to the onboard PAL/
NTSC encoder for full screen video images.
HSYNC and B/T generation or lock onto
external video timing source.
Video Pipeline
Two-tap interpolative horizontal filter.
Two-tap interpolative vertical filter.
Color space conversion (RGB to YUV and
YUV to RGB).
Programmable window size.
Chroma and color keying for integrated video
overlay.
Programmable two tap filter with gamma
correction or three tap flicker filter.
Progressive to interlaced scan converter.
Digital NTSC/PAL encoder
NTSC-M, PAL-M,PAL-B,D,G,H,I,PAL-N easy
programmable video outputs.
CCIR601 encoding with programmable color
subcarrier frequencies.
Line skip/insert capability
Interlaced or non-interlaced operation mode.
625 lines/50Hz or 525 lines/60Hz 8 bit
multiplexed CB-Y-CR digital input.
CVBS and R,G,B simultaneous analog
outputs through 10-bit DACs.
Cross color reduction by specific trap filtering
on luma within CVBS flow.
Power down mode available on each DAC.
STPC CONSUMER
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PCI Controller
Fully compliant with PCI 2.1 specification.
Integrated PCI arbitration interface. Up to 3
masters can connect directly. External PAL
allows for greater than 3 masters.
Translation of PCI cycles to ISA bus.
Translation of ISA master initiated cycle to
PCI.
Support for burst read/write from PCI master.
0.33X and 0.5X CPU clock PCI clock.
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ISA master/slave Interface
Generates the ISA clock from either
14.318MHz oscillator clock or PCI clock
Supports programmable extra wait state for
ISA cycles
Supports I/O recovery time for back to back
I/O cycles.
Fast Gate A20 and Fast reset.
Supports the single ROM that C, D, or E.
blocks shares with F block BIOS ROM.
Supports flash ROM.
Supports ISA hidden refresh.
Buffered DMA & ISA master cycles to reduce
bandwidth utilization of the PCI and Host bus.
NSP compliant.
IDE Interface
Supports PIO
Supports up to Mode 5 Timings
Transfer Rates to 22 MBytes/sec
Supports up to 4 IDE devices
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Concurrent channel operation (PIO modes) 4 x 32-Bit Buffer FIFOs per channel
Support for PIO mode 3 & 4.
Support for 11.1/16.6 MB/s, I/O Channel
Ready PIO data transfers.
Individual drive timing for all four IDE devices
Supports both legacy & native IDE modes
Supports hard drives larger than 528MB
Support for CD-ROM and tape peripherals
Backward compatibility with IDE (ATA-1).
Drivers for Windows and other Operating
Systems
Integrated peripheral controller
2X8237/AT compatible 7-channel DMA
controller.
2X8259/AT compatible interrupt Controller.
16 interrupt inputs - ISA and PCI.
Three 8254 compatible Timer/Counters.
Co-processor error support logic.
Power Management
Four power saving modes: On, Doze,
Standby, Suspend.
Programmable system activity detector
Supports SMM and APM.
Supports STOPCLK.
Supports IO trap & restart.
Independent peripheral time-out timer to
monitor hard disk, serial & parallel ports.
Supports RTC, interrupts and DMAs wake-up
3/51
Issue 1.2
STPC CONSUMER
4/51
Issue 1.2
UPDATE HISTORY FOR OVERVIEW.
0.1 UPDATE HISTORY FOR OVERVIEW.
The following changes have been made to the Electrical Specification Chapter on the 02/02/2000.
Section
Change
Text
Added
To check if your memory device is supported by the STPC, please refer to
Table 9-3 Host Address to MA Bus Mappingin the Programming Manual.
5/51
Issue 1.2
GENERAL DESCRIPTION
1. GENERAL DESCRIPTION
At the heart of the STPC Consumer is an advanced processor block, dubbed the 5ST86. The
5ST86 includes a powerful x86 processor core
along with a 64-bit DRAM controller, advanced
64bit accelerated graphics and video controller, a
high speed PCI local-bus controller and Industry
standard PC chip set functions (Interrupt controller, DMA Controller, Interval timer and ISA bus)
and EIDE controller.
The STPC Consumer has in addition to the
5ST86, a Video subsystem and high quality digital
Television output.
The STMicroelectronics x86 processor core is embedded with standard and application specific peripheral modules on the same silicon die. The core
has all the functionality of the STMicroelectronics
standard x86 processor products, including the
low power System Management Mode (SMM).
System Management Mode (SMM) provides an
additional interrupt and address space that can be
used for system power management or software
transparent emulation of peripherals. While running in isolated SMM address space, the SMM interrupt routine can execute without interfering with
the operating system or application programs.
Further power management facilities include a
suspend mode that can be initiated from either
hardware or software. Because of the static nature
of the core, no internal data is lost.
The STPC Consumer makes use of a tightly coupled Unified Memory Architecture (UMA), where
the same memory array is used for CPU main
memory and graphics frame-buffer. This significantly reduces total system memory with system
performances equal to that of a comparable solution with separate frame buffer and system memory. In addition, memory bandwidth is improved by
attaching the graphics engine directly to the 64-bit
processor host interface running at the speed of
the processor bus rather than the traditional PCI
bus.
The 64-bit wide memory array provides the system with 320MB/s peak bandwidth, double that of
an equivalent system using 32 bits. This allows for
higher screen resolutions and greater color depth.
The processor bus runs at the speed of the processor (DX devices) or half the speed (DX2 devices).
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Issue 1.2
The ‘standard’ PC chipset functions (DMA, interrupt controller, timers, power management logic)
are integrated with the x86 processor core.
The PCI bus is the main data communication link
to the STPC Consumer chip. The STPC Consumer translates appropriate host bus I/O and Memory
cycles onto the PCI bus. It also supports the generation of Configuration cycles on the PCI bus.
The STPC Consumer, as a PCI bus agent (host
bridge class), fully complies with PCI specification
2.1. The chip-set also implements the PCI mandatory header registers in Type 0 PCI configuration
space for easy porting of PCI aware system BIOS. The device contains a PCI arbitration function
for three external PCI devices.
The STPC Consumer integrates an ISA bus controller. Peripheral modules such as parallel and
serial communications ports, keyboard controllers
and additional ISA devices can be accessed by
the STPC Consumer chip set through this bus.
An industry standard EIDE (ATA 2) controller is
built in to the STPC Consumer and connected internally via the PCI bus.
Graphics functions are controlled by the on-chip
SVGA controller and the monitor display is managed by the 2D graphics display engine.
This Graphics Engine is tuned to work with the
host CPU to provide a balanced graphics system
with a low silicon area cost. It performs limited
graphics drawing operations, which include hardware acceleration of text, bitblts, transparent blts
and fills. These operations can act on off-screen
or on-screen areas. The frame buffer size ranges
up to 4 Mbytes anywhere in the physical main
memory.
The graphics resolution supported is a maximum
of 1280x1024 in 65536 colours at 75Hz refresh
rate and is VGA and SVGA compatible. Horizontal
timing fields are VGA compatible while the vertical
fields are extended by one bit to accommodate the
above display resolution.
STPC Consumer provides several additional functions to handle MPEG or similar video streams.
The Video Input Port accepts an encoded digital
video stream in one of a number of industry standard formats, decodes it, optionally decimates it by
a factor of 2:1, and deposits it into an off screen
area of the frame buffer. An interrupt request can
be generated when an entire field or frame has
been captured.
GENERAL DESCRIPTION
The video output pipeline incorporates a videoscaler and color space converter function and provisions in the CRT controller to display a video
window. While repainting the screen the CRT controller fetches both the video as well as the normal
non-video frame buffer in two separate internal
FIFOs (256-Bytes each). The video stream can be
color-space converted (optionally) and smooth
scaled. Smooth interpolative scaling in both horizontal and vertical directions are implemented.
Color and Chroma key functions are also implemented to allow mixing video stream with non-video frame buffer.
The video output passes directly to the RAMDAC
for monitor output or through another optional
color space converter (RGB to 4:2:2 YCrCb) to the
programmable anti-flicker filter. The flicker filter is
configured as either a two line filter with gamma
correction (primarily designed for DOS type text)
or a 3 line flicker filter (primarily designed for Windows type displays). The flicker filter is optional
and can be software disabled for use with video on
large screen areas.
The Video output pipeline of the STPC Consumer
interfaces directly to the internal digital TV encoder. It takes a 24 bit RGB non-interlaced pixel
stream and converts to a multiplexed 4:2:2 YCrCb
8 bit output stream, the logic includes a progressive to interlaced scan converter and logic to insert appropriate CCIR656 timing reference codes
into the output stream. It facilitates the high quality
display of VGA or full screen video streams received via the Video input port to standard NTSC
or PAL televisions.
The STPC Consumer core is compliant with the
Advanced Power Management (APM) specification to provide a standard method by which the
BIOS can control the power used by personal
computers. The Power Management Unit module
(PMU) controls the power consumption by providing a comprehensive set of features that control
the power usage and supports compliance with
the United States Environmental Protection Agency’s Energy Star Computer Program. The PMU
provides following hardware structures to assist
the software in managing the power consumption
by the system.
- System Activity Detection.
- 3 power-down timers detecting system inactivity:
- House-keeping timer to cope with short bursts of
house-keeping activity while dozing or in stand-by
state.
- Peripheral activity detection.
- Peripheral timer detecting peripheral inactivity
- SUSP# modulation to adjust the system performance in various power down states of the system
including full power on state.
- Power control outputs to disable power from different planes of the board.
Lack of system activity for progressively longer
period of times is detected by the three power
down timers. These timers can generate SMI interrupts to CPU so that the SMM software can put
the system in decreasing states of power consumption. Alternatively, system activity in a power
down state can generate SMI interrupt to allow the
software to bring the system back up to full power
on state. The chip-set supports up to three power
down states: Doze state, Stand-by state and Suspend mode. These correspond to decreasing levels of power savings.
Power down puts the STPC Consumer into suspend mode. The processor completes execution
of the current instruction, any pending decoded instructions and associated bus cycles. During the
suspend mode, internal clocks are stopped. Removing power down, the processor resumes instruction fetching and begins execution in the instruction stream at the point it had stopped.
A reference design for the STPC Consumer is
available including the schematics and layout
files, the design is a PC ATX motherboard design.
The design is available as a demonstration board
for application and system development.
The STPC Consumer is supported by several
BIOS vendors, including the super I/O device
used in the reference design. Drivers for 2D accelerator, video features and EIDE are availaible on
various operating systems.
The STPC Consumer has been designed using
modern reusable modular design techniques, it is
possible to add or remove the standard features of
the STPC Consumer or other variants of the
5ST86 family. Contact your local STMicroelectonics sales office for further information.
- Doze timer (short durations).
- Stand-by timer (medium durations).
- Suspend timer (long durations).
- House-keeping activity detection.
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Issue 1.2
GENERAL DESCRIPTION
Figure 1-1 Functionnal description
x86
Core
ISA BUS
Host I/F
ISA
IPC
PCI m/s
EIDE
EIDE
PCI BUS
PCI m/s
CCIR Input
VIP
TV Output
Digital
PAL/
Anti-Flicker
Video
pipeline
Color
Key
2D
SVGA
Chroma
CRTC
Color Space
Monitor
HW Cursor
SYNC Output
DRAM
8/51
Issue 1.2
GENERAL DESCRIPTION
Figure 1-2 Typical Application
Keyboard / Mouse
Serial Ports
Parallel Port
Floppy
Super I/O
RTC
Flash
2x EIDE
ISA
DMUX
MUX
Monitor
IRQ
SVGA
MUX
DMA.REQ
TV
STPC Consumer
S-VHS
RGB
PAL
NTSC
DMA.ACK
DMUX
Video
CCIR601
CCIR656
PCI
4x 16-bit EDO DRAMs
9/51
Issue 1.2
PIN DESCRIPTION
2. PIN DESCRIPTION
2.1 INTRODUCTION
The STPC Consumer integrates most of the functionalities of the PC architecture. As a result, many
of the traditional interconnections between the
host PC microprocessor and the peripheral devices are totally internal to the STPC Consumer. This
offers improved performance due to the tight coupling of the processor core and these peripherals.
As a result many of the external pin connections
are made directly to the on-chip peripheral functions.
Table 2-1. Signal Description
Figure 2-1 shows the STPC Consumer’s external
interfaces. It defines the main busses and their
function. Table 2-1 describes the physical implementation listing signal types and their functionalities. Table 2-2 provides a full pin listing and description. Table 2-3 provides a full listing of the
STPC Consumer pin locations of package by
physical connection. Please refer to the pin allocation drawing for reference.
Group name
Basic Clocks reset & Xtal(SYS)
Qty
12
DRAM Controller
PCI interface (PCI)
ISA / IDE / IPC combined interface
Video Input (VIP)
TV Output
VGA Monitor interface
Grounds
VDD
Analog specific VCC/VDD
Reserved
Total Pin Count
89
58
88
9
10
10
69
26
12
5
388
Note: Several interface pins are multiplexed with
other functions, refer to the Pin Description section for further details
Figure 2-1. STPC Consumer External Interfaces
STPC Consumer
x86
NORTH
PCI
DRAM
VGA
VIP
TV
89
10
9
10
58
10/51
Issue 1.2
SOUTH
SYS
ISA/IDE
IPC
13
77
11
PIN DESCRIPTION
Table 2-2. Definition of Signal Pins
Signal Name
BASIC CLOCKS AND RESETS
SYSRSTI#
XTALI
XTALO
HCLK
DEV_CLK
GCLK2X
DCLK
PCI_CLKI
PCI_CLKO
SYSRSTO#
ISA_CLK
ISA_CLK2X
Dir
Description
Qty
I
I
I/O
O
O
I/O
I/O
I
O
O
O
O
System Reset / Power good
14.3MHz Crystal Input
14.3MHz Crystal Output - External Oscillator Input
Host Clock (Test)
24MHz Peripheral Clock (floppy drive)
80MHz Graphics Clock
135MHz Dot Clock
33MHz PCI Input Clock
33MHz PCI Output Clock (from internal PLL)
Reset Output to System
ISA Clock Output - Multiplexer Select Line For IPC
ISA Clock x 2 Output - Multiplexer Select Line For IPC
MEMORY INTERFACE
MA[11:0]
RAS#[3:0]
CAS#[7:0]
MWE#
MD[63:0]
I/O
O
O
O
I/O
Memory Address
Row Address Strobe
Column Address Strobe
Write Enable
Memory Data
12
4
8
1
64
PCI INTERFACE
AD[31:0]
CBE[3:0]
FRAME#
TRDY#
IRDY#
STOP#
DEVSEL#
PAR
SERR#
LOCK#
PCIREQ#[2:0]
PCIGNT#[2:0]
I/O
I/O
I/O
I/O
I/O
I/O
I/O
I/O
O
I
I
O
PCI Address / Data
Bus Commands / Byte Enables
Cycle Frame
Target Ready
Initiator Ready
Stop Transaction
Device Select
Parity Signal Transactions
System Error
PCI Lock
PCI Request
PCI Grant
32
4
1
1
1
1
1
1
1
1
3
3
PCI_INT[3:0]
VDD5
I
I
PCI Interrupt Request
5V Power Supply for PCI ESD protection
ISA AND IDE COMBINED ADDRESS/DATA
LA[23:22] / SCS3#,SCS1#
I/O
Unlatched Address (ISA) / Secondary Chip Select (IDE)
LA[21:20] / PCS3#,PCS1#
I/O
Unlatched Address (ISA) / Primary Chip Select (IDE)
LA[19:17] / DA[2:0]
O
Unlatched Address (ISA) / Address (IDE)
RMRTCCS# / DD[15]
I/O
ROM/RTC Chip Select / Data Bus bit 15 (IDE)
KBCS# / DD[14]
I/O
Keyboard Chip Select / Data Bus bit 14 (IDE)
RTCRW# / DD[13]
I/O
RTC Read/Write / Data Bus bit 13 (IDE)
RTCDS# / DD[12]
I/O
RTC Data Strobe / Data Bus bit 12 (IDE)
SA[19:8] / DD[11:0]
SA[7:0]
SD[15:0]
I/O
I/O
I/O
Latched Address (ISA) / Data Bus (IDE)
Latched Address (IDE)
Data Bus (ISA)
1
1
1
1
1
1
1
1
1
1
1
1
4
4
2
2
3
1
1
1
1
16
4
16
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Issue 1.2
PIN DESCRIPTION
Table 2-2. Definition of Signal Pins
Signal Name
Dir
Description
ISA/IDE COMBINED CONTROL
IOCHRDY / DIORDY
I/O
I/O Channel Ready (ISA) - Busy/Ready (IDE)
1
ISA CONTROL
OSC14M
ALE
BHE#
MEMR#, MEMW#
SMEMR#, SMEMW#
IOR#, IOW#
MASTER#
MCS16#, IOCS16#
REF#
AEN
ZWS#
IOCHCK#
ISAOE#
RTCAS#
GPIOCS#
O
O
I/O
I/O
O
I/O
I
I
O
O
I
I
O
O
I/O
ISA bus synchronisation clock
Address Latch Enable
System Bus High Enable
Memory Read and Memory Write
System Memory Read and Memory Write
I/O Read and Write
Add On Card Owns Bus
Memory/IO Chip Select16
Refresh Cycle.
Address Enable
Zero Wait State
I/O Channel Check.
Bidirectional OE Control
Real Time Clock Address Strobe
General Purpose Chip Select
1
1
1
2
2
2
1
2
1
1
1
1
1
1
1
IDE CONTROL
PIRQ
SIRQ
PDRQ
SDRQ
PDACK#
SDACK#
PIOR#
PIOW#
SIOR#
SIOW#
I
I
I
I
O
O
I/O
O
I/O
O
Primary Interrupt Request
Secondary Interrupt Request
Primary DMA Request
Secondary DMA Request
Primary DMA Acknowledge
Secondary DMA Acknowledge
Primary I/O Read
Primary I/O Write
Secondary I/O Read
Secondary I/O Write
1
1
1
1
1
1
1
1
1
1
IPC
IRQ_MUX[3:0]
DREQ_MUX[1:0]
DACK_ENC[2:0]
TC
I
I
O
O
Multiplexed Interrupt Request
Multiplexed DMA Request
DMA Acknowledge
ISA Terminal Count
4
2
3
1
MONITOR INTERFACE
RED, GREEN, BLUE
VSYNC
HSYNC
VREF_DAC
RSET
O
O
O
I
I
Red, Green, Blue
Vertical Sync
Horizontal Sync
DAC Voltage reference
Resistor Set
3
1
1
1
1
COMP
DDC[1:0]
SCL / DDC[1]
I
I/O
I/O
Compensation
Display Data Channel Serial Link
I C Interface - Clock / Can be used for VGA DDC[1] signal
1
2
1
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Issue 1.2
Qty
PIN DESCRIPTION
Table 2-2. Definition of Signal Pins
Signal Name
SDA / DDC[0]
COL_CMP
Dir
I/O
O
Description
I C Interface - Data / Can be used for VGA DDC[0] signal
Color Compare Output.
Qty
1
VIDEO INPUT
VCLK
VIN
I
I
Pixel Clock
YUV Video Data Input CCIR 601 or 656
1
8
DIGITAL TV OUTPUT
RED_TV, GREEN_TV, BLUE_TV
VCS
ODD_EVEN
CVBS
IREF1_TV
VREF1_TV
IREF2_TV
VREF2_TV
VSSA_TV
VDDA_TV
O
O
O
O
I
I
I
I
I
I
Analog video outputs synchronized with CVBS
Composite Synch or Horizontal line SYNC output
Frame Synchronisation
Analog video composite output (luminance / chrominance)
Reference current of 9bit DAC for CVBS
Reference voltage of 9bit DAC for CVBS
Reference current of 8bit DAC for R,G,B
Reference voltage of 8bit DAC for R,G,B
Analog Vss for DAC
Analog Vdd for DAC
3
1
1
1
1
1
1
1
1
1
MISCELLANEOUS
SPKRD
SCAN_ENABLE
O
I
Speaker Device Output
Reserved (Test pin)
1
1
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Issue 1.2
PIN DESCRIPTION
2.2 SIGNAL DESCRIPTIONS
2.2.1 BASIC CLOCKS AND RESETS
SYSRSTI System Reset/Power good. This input is
low when the reset switch is depressed. Otherwise, it reflects the power supply’s power good
signal. SYSRSTI is asynchronous to all clocks,
and acts as a negative active reset. The reset circuit initiates a hard reset on the rising edge of
SYSRSTI.
SYSRSTO# Reset Output to System. This is the
system reset signal and is used to reset the rest of
the components (not on Host bus) in the system.
The ISA bus reset is an externally inverted buffered version of this output and the PCI bus reset is
an externally buffered version of this output.
XTALI 14.3MHz Crystal Input
XTALO 14.3MHz Crystal Output. These pins are
the 14.318 MHz crystal input; This clock is used as
the reference clock for the internal frequency synthesizer to generate the HCLK, CLK24M,
GCLK2X and DCLK clocks.
A 14.318 MHz Series Cut Quartz Crystal should
be connected between these two pins. Balance
capacitors of 15 pF should also be added. In the
event of an external oscillator providing the master
clock signal to the STPC Consumer device, the
TTL signal should be provided on XTALO.
HCLK Host Clock. This is the host 1X clock. Its
frequency can vary from 25 to 75 MHz. All host
transactions and PCI transactions are synchronized to this clock. The DRAM controller to execute the host transactions is also driven by this
clock. In normal mode, this output clock is generated by the internal pll.
GCLK2X 80MHz Graphics Clock. This is the
Graphics 2X clock, which drives the graphics engine and the DRAM controller to execute the
graphics and display cycles.
Normally GCLK2X is generated by the internal frequency synthesizer, and this pin is an output. By
setting a bit in Strap Register 2, this pin can be
made an input so that an external clock can replace the internal frequency synthesizer.
PCI_CLKI 33MHz PCI Input Clock
This signal is the PCI bus clock input and should
be driven from the PCI_CLKO pin.
PCI_CLKO 33MHz PCI Output Clock. This is the
master PCI bus clock output.
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Issue 1.2
DCLK 135MHz Dot Clock. This is the dot clock,
which drives graphics display cycles. Its frequency
can go from 8MHz (using internal PLL) up to 135
MHz, and it is required to have a worst case duty
cycle of 60-40.
This signal is either driven by the internal pll (VGA)
or an external 27MHz oscillator (when the composite video output is enabled). The direction can
be controlled by a strap option or an internal register bit.
ISA_CLK ISA Clock Output (also Multiplexer Select Line For IPC). This pin produces the Clock
signal for the ISA bus. It is also used with
ISA_CLK2X as the multiplexor control lines for the
Interrupt Controller Interrupt input lines. This is a
divided down version of either the PCICLK or
OSC14M.
ISA_CLKX2 ISA Clock Output (also Multiplexer
Select Line For IPC). This pin produces a signal
that is twice the frequency of the ISA bus Clock
signal. It is also used with ISA_CLK as the multiplexor control lines for the Interrupt Controller input lines.
DEV_CLK 24MHz Peripheral Clock Output. This
24MHZ signal is provided as a convenience for
the system integration of a Floppy Disk driver
function in an external chip.
OSC14M ISA bus synchronisation clock Output.
This is the buffered 14.318 Mhz clock to the ISA
bus.
2.2.2 MEMORY INTERFACE
MA[11:0] Memory Address Output. These 12 multiplexed memory address pins support external
DRAM with up to 4K refresh. These include all
16M x N and some 4M x N DRAM modules. The
address signals must be externally buffered to
support more than 16 DRAM chips. The timing of
these signals can be adjusted by software to
match the timings of most DRAM modules.
PIN DESCRIPTION
MD[63:0] Memory Data I/O. This is the 64-bit
memory data bus. If only half of a bank is populated, MD63-32 is pulled high, data is on MD31-0.
MD[40-0] are read by the device strap option registers during rising edge of SYSRSTI.
RAS#[3:0] Row Address Strobe Output. There
are 4 active low row address strobe outputs, one
for each bank of the memory. Each bank contains
4 or 8-Bytes of data. The memory controller allows
half of a bank (4-bytes) to be populated to enable
memory upgrade at finer granularity.
The RAS# signals drive the SIMMs directly without any external buffering. These pins are always
outputs, but they can also simultaneously be inputs, to allow the memory controller to monitor the
value of the RAS# signals at the pins.
CAS#[7:0] Column Address Strobe Output. There
are 8 active low column address strobe outputs,
one each for each byte of the memory.
The CAS# signals drive the SIMMs either directly
or through external buffers.
These pins are always outputs, but they can also
simultaneously be inputs, to allow the memory
controller to monitor the value of the CAS# signals
at the pins.
MWE# Write Enable Output. Write enable specifies whether the memory access is a read (MWE#
= H) or a write (MWE# = L). This single write enable controls all the DRAM. It can be externally
buffered to boost the maximum number of loads
(DRAM chips) supported.
The MWE# signals drive the SIMMs directly without any external buffering.
simple analog low pass filter is recommended. In
S-VHS mode, this is the Chrominance Output.
GREEN_TV / Y_TV Analog video outputs synchronized with CVBS. This output is current-driven and must be connected to analog ground over
a load resistor (RLOAD). Following the load resistor, a simple analog low pass filter is recommended. In S-VHS mode, this is the Luminance Output.
BLUE_TV / CVBSAnalog video outputs synchronized with CVBS. This output is current-driven and
must be connected to analog ground over a load
resistor (RLOAD). Following the load resistor, a
simple analog low pass filter is recommended. In
S-VHS mode, this is a second composite output.
VCS Line synchronisation Output. This pin is an
input in ODDEV+HSYNC or VSYNC + HSYNC or
VSYNC slave modes and an output in all other
modes (master/slave)
The signal is synchronous to rising edge of CKREF. The default polarity uses a negative pulse
ODD_EVEN Frame Synchronisation Ourput. This
pin supports the Frame synchronisation signal. It
is an input in slave modes, except when sync is
extracted from YCrCb data, and an output in master mode and when sync is extracted from YCrCb
data
The signal is synchronous to rising edge of DCLK.
The default polarity for this pin is:
- odd (not-top) field : LOW level
- even (bottom) field : HIGH level
IREF1_TV Ref. current for CVBS 10-bit DAC.
2.2.3 VIDEO INTERFACE
VREF1_TV Ref. voltage for CVBS 10-bit DAC.
VCLK Pixel Clock Input.
IREF2_TV Reference current for RGB 9-bit DAC.
VIN[7:0] YUV Video Data Input CCIR 601 or 656.
Time multiplexed 4:2:2 luminance and chrominance data as defined in ITU-R Rec601-2 and
Rec656 (except for TTL input levels). This bus interfaces with an MPEG video decoder output port
and typically carries a stream of Cb,Y,Cr,Y digital
video at VCLK frequency, clocked on the rising
edge (by default) of VCLK. A 54-Mbit/s ‘double’
Cb, Y, Cr, Y input multiplex is supported for double
encoding application (rising and falling edge of
CKREF are operating).
VREF2_TV Reference voltage for RGB 9-bit DAC.
2.2.4 TV OUTPUT
2.2.5 PCI INTERFACE
RED_TV / C_TV Analog video outputs synchronized with CVBS. This output is current-driven and
must be connected to analog ground over a load
resistor (RLOAD). Following the load resistor, a
AD[31:0] PCI Address/Data. This is the 32-bit
multiplexed address and data bus of the PCI. This
bus is driven by the master during the address
phase and data phase of write transactions. It is
VSSA_TV Analog VSS for DAC
VDDA_TV Analog VDD for DAC
CVBS Analog video composite output (luminance/
chrominance). CVBS is current-driven and must
be connected to analog ground over a load resistor (R LOAD). Following the load resistor, a simple
analog low pass filter is recommended.
15/51
Issue 1.2
PIN DESCRIPTION
driven by the target during data phase of read
transactions.
CBE#[3:0] Bus Commands/Byte Enables. These
are the multiplexed command and byte enable
signals of the PCI bus. During the address phase
they define the command and during the data
phase they carry the byte enable information.
These pins are inputs when a PCI master other
than the STPC Consumer owns the bus and outputs when the STPC Consumer owns the bus.
SERR# System Error. This is the system error signal of the PCI bus. It may, if enabled, be asserted
for one PCI clock cycle if target aborts a STPC
Consumer initiated PCI transaction. Its assertion
by either the STPC Consumer or by another PCI
bus agent will trigger the assertion of NMI to the
host CPU. This is an open drain output.
LOCK# PCI Lock. This is the lock signal of the PCI
bus and is used to implement the exclusive bus
operations when acting as a PCI target agent.
FRAME# Cycle Frame. This is the frame signal of
the PCI bus. It is an input when a PCI master owns
the bus and is an output when STPC Consumer
owns the PCI bus.
PCIREQ#[2:0] PCI Request. This pin are the
three external PCI master request pins. They indicates to the PCI arbiter that the external agents
desire use of the bus.
TRDY# Target Ready. This is the target ready signal of the PCI bus. It is driven as an output when
the STPC Consumer is the target of the current
bus transaction. It is used as an input when STPC
Consumer initiates a cycle on the PCI bus.
PCIGNT#[2:0] PCI Grant. These pins indicate that
the PCI bus has been granted to the master requesting it on its PCIREQ#.
IRDY# Initiator Ready. This is the initiator ready
signal of the PCI bus. It is used as an output when
the STPC Consumer initiates a bus cycle on the
PCI bus. It is used as an input during the PCI cycles targeted to the STPC Consumer to determine
when the current PCI master is ready to complete
the current transaction.
LA[23]/SCS3# Unlatched Address (ISA)/Secondary Chip Select (IDE). This pin has two functions,
depending on whether the ISA bus is active or the
IDE bus is active.
When the ISA bus is active, this pins is ISA Bus
unlatched address bit 23 for 16-bit devices. When
ISA bus is accessed by any cycle initiated from
PCI bus, this pin is in output mode. When an ISA
bus master owns the bus, this pins is in input
mode.
When the IDE bus is active, this signals is used as
the active high secondary slave IDE chip select
signal. This signal is to be externally NANDed with
the ISAOE# signal before driving the IDE devices
to guarantee it is active only when ISA bus is idle.
STOP# Stop Transaction. Stop is used to implement the disconnect, retry and abort protocol of
the PCI bus. It is used as an input for the bus cycles initiated by the STPC Consumer and is used
as an output when a PCI master cycle is targeted
to the STPC Consumer.
DEVSEL# I/O Device Select. This signal is used
as an input when the STPC Consumer initiates a
bus cycle on the PCI bus to determine if a PCI
slave device has decoded itself to be the target of
the current transaction. It is asserted as an output
either when the STPC Consumer is the target of
the current PCI transaction or when no other device asserts DEVSEL# prior to the subtractive decode phase of the current PCI transaction.
PAR Parity Signal Transactions. This is the parity
signal of the PCI bus. This signal is used to guarantee even parity across AD[31:0], CBE#[3:0],
and PAR. This signal is driven by the master during the address phase and data phase of write
transactions. It is driven by the target during data
phase of read transactions. (Its assertion is identical to that of the AD bus delayed by one PCI clock
cycle)
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Issue 1.2
2.2.6 ISA/IDE COMBINED ADDRESS/DATA
PIN DESCRIPTION
LA[22]/SCS1# Unlatched Address (ISA)/Secondary Chip Select (IDE)
This pin has two functions, depending on whether
the ISA bus is active or the IDE bus is active.
When the ISA bus is active, this pins is ISA Bus
unlatched address bit 22 for 16-bit devices. When
ISA bus is accessed by any cycle initiated from
PCI bus, this pin is in output mode. When an ISA
bus master owns the bus, this pins is in input
mode.
When the IDE bus is active, this signals is used as
the active high secondary slave IDE chip select
signal. This signal is to be externally ANDed with
the ISAOE# signal before driving the IDE devices
to guarantee it is active only when ISA bus is idle.
LA[21]/PCS3# Unlatched Address (ISA)/Primary
Chip Select (IDE). This pin has two functions, depending on whether the ISA bus is active or the
IDE bus is active.
When the ISA bus is active, this pins is ISA Bus
unlatched address bit 21 for 16-bit devices. When
ISA bus is accessed by any cycle initiated from
PCI bus, this pin is in output mode. When an ISAbus master owns the bus, this pins is in input
mode.
When the IDE bus is active, this signals is used as
the active high primary slave IDE chip select signal. This signal is to be externally NANDed with
the ISAOE# signal before driving the IDE devices
to guarantee it is active only when ISA bus is idle.
LA[20]/PCS1# Unlatched Address (ISA)/Primary
Chip Select (IDE). This pin has two functions, depending on whether the ISA bus is active or the
IDE bus is active.
When the ISA bus is active, this pins is ISA Bus
unlatched address bit 20 for 16-bit devices. When
ISA bus is accessed by any cycle initiated from
PCI bus, this pin is in output mode. When an ISA
bus master owns the bus, this pins is in input
mode.
When the IDE bus is active, this signals is used as
the active high primary slave IDE chip select signal. This signal is to be externally NANDed with
the ISAOE# signal before driving the IDE devices
to guarantee it is active only when ISA bus is idle.
LA[19:17]/DA[2:0] Unlatched Address (ISA)/Address (IDE). These pins are multi-function pins.
They are used as the ISA bus unlatched address
bits [19:17] for ISA bus or the three address bits
for the IDE bus devices.
When used by the ISA bus, these pins are ISA
Bus unlatched address bits 19-17 on 16-bit devices. When ISA bus is accessed by any cycle initiated from the PCI bus, these pins are in output
mode. When an ISA bus master owns the bus,
these pins are tristated.
For IDE devices, these signals are used as the
DA[2:0] and are connected to DA[2:0] of IDE devices directly or through a buffer. If the toggling of
signals are to be masked during ISA bus cycles,
they can be externally ORed before being connected to the IDE devices.
SA[19:8]/DD[11:0] Unlatched Address (ISA)/Data
Bus (IDE). These are multifunction pins. When the
ISA bus is active, they are used as the ISA bus
system address bits 19-8. When the IDE bus is active, they serve as IDE signals DD[11:0].
These pins are used as an input when an ISA bus
master owns the bus and are outputs at all other
times.
IDE devices are connected to SA[19:8] directlyand
ISA bus is connected to these pins through two
LS245 transceivers. The OE of the transceivers
are connected to ISAOE # and DIR is connected to
MASTER#. A bus signals of the transceivers are
connected to CPC and IDE DD bus and B bus signals are connected to ISA SA bus.
DD[15:12] Databus (IDE). The high 4 bits of the
IDE databus are combined with several of the Xbus lines. Refer to the following section for X-bus
pins for further information.
SA[7:0] ISA Bus address bits [7:0]. These are the
8 low bits of the system address bus of ISA on 8bit slot. These pins are used as an input when an
ISA bus master owns the bus and are outputs at
all other times.
SD[15:0] I/O Data Bus (ISA). These pins are the
external databus to the ISA bus.
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Issue 1.2
PIN DESCRIPTION
2.2.7 ISA/IDE COMBINED CONTROL
IOCHRDY/DIORDY Channel Ready (ISA)/Busy/
Ready (IDE). This is a multi-function pin. When
the ISA bus is active, this pin is IOCHRDY. When
the IDE bus is active, this serves as IDE signal DIORDY.
IOCHRDY is the IO channel ready signal of the
ISA bus and is driven as an output in response to
an ISA master cycle targeted to the host bus or an
internal register of the STPC Consumer. The
STPC Consumer monitors this signal as an input
when performing an ISA cycle on behalf of the
host CPU, DMA master or refresh.
ISA masters which do not monitor IOCHRDY are
not guaranteed to work with the STPC Consumer
since the access to the system memory can be
considerably delayed due to CRT refresh or a
write back cycle.
2.2.8 ISA CONTROL
ALE Address Latch Enable. This is the address
latch enable output of the ISA bus and is asserted
by the STPC Consumer to indicate that LA23-17,
SA19-0, AEN and SBHE# signals are valid. The
ALE is driven high during refresh, DMA master or
an ISA master cycles by the STPC Consumer.
ALE is driven low after reset.
BHE# System Bus High Enable. This signal, when
asserted, indicates that a data byte is being transferred on SD15-8 lines. It is used as an input when
an ISA master owns the bus and is an output at all
other times.
MEMR# Memory Read. This is the memory read
command signal of the ISA bus. It is used as an input when an ISA master owns the bus and is an
output at all other times.
The MEMR# signal is active during refresh.
IOR# I/O Read. This is the IO read command signal of the ISA bus. It is an input when an ISA master owns the bus and is an output at all other
times.
IOW# I/O Write. This is the IO write command signal of the ISA bus. It is an input when an ISA master owns the bus and is an output at all other
times.
MASTER# Add On Card Owns Bus. This signal is
active when an ISA device has been granted bus
ownership.
MCS16# Memory Chip Select16. This is the decode of LA23-17 address pins of the ISA address
bus without any qualification of the command signal lines. MCS16# is always an input. The STPC
Consumer ignores this signal during IO and refresh cycles.
IOCS16# IO Chip Select16. This signal is the decode of SA15-0 address pins of the ISA address
bus without any qualification of the command signals. The STPC Consumer does not drive
IOCS16# (similar to PC-AT design). An ISA master access to an internal register of the STPC Consumer is executed as an extended 8-bit IO cycle.
REF# Refresh Cycle. This is the refresh command
signal of the ISA bus. It is driven as an output
when the STPC Consumer performs a refresh cycle on the ISA bus. It is used as an input when an
ISA master owns the bus and is used to trigger a
refresh cycle.
The STPC Consumer performs a pseudo hidden
refresh. It requests the host bus for two host
clocks to drive the refresh address and capture it
in external buffers. The host bus is then relinquished while the refresh cycle continues on the
ISA bus.
MEMW# Memory Write. This is the memory write
command signal of the ISA bus. It is used as an input when an ISA master owns the bus and is an
output at all other times.
AEN Address Enable. Address Enable is enabled
when the DMA controller is the bus owner to indicate that a DMA transfer will occur. The enabling
of the signal indicates to IO devices to ignore the
IOR#/IOW# signal during DMA transfers.
SMEMR# System Memory Read. The STPC Consumer generates SMEMR# signal of the ISA bus
only when the address is below one megabyte or
the cycle is a refresh cycle.
ZWS# Zero Wait State. This signal, when asserted by addressed device, indicates that current cycle can be shortened.
SMEMW# System Memory Write. The STPC Consumer generates SMEMW# signal of the ISA bus
only when the address is below one megabyte.
This signal is multiplexed with COL_CMP on the
VGA Interface. The signal is selected by setting
Strap Option MD[0] as described in Section 3.
18/51
Issue 1.2
IOCHCK# IO Channel Check. IO Channel Check
is enabled by any ISA device to signal an error
condition that can not be corrected. NMI signal becomes active upon seeing IOCHCK# active if the
corresponding bit in Port B is enabled.
PIN DESCRIPTION
ISAOE# Bidirectional OE Control. This signal controls the OE signal of the external transceiver that
connects the IDE DD bus and ISA SA bus.
coded before connection to the STPC Consumer
using ISACLK and ISACLKX2 as the input selection strobes.
GPIOCS# I/O General Purpose Chip Select 1.
This output signal is used by the external latch on
ISA bus to latch the data on the SD[7:0] bus. The
latch can be use by PMU unit to control the external peripheral devices to power down or any other
desired function.
This pin is also serves as a strap input during reset.
DREQ_MUX[1:0] ISA Bus Multiplexed DMA Request. These are the ISA bus DMA request signals. They are to be encoded before connection to
the STPC Consumer using ISACLK and
ISACLKX2 as the input selection strobes.
2.2.9 IDE CONTROL
PIRQ Primary Interrupt Request. Interrupt request
from primary IDE channel.
SIRQ Secondary Interrupt Request. Interrupt request from secondary IDE channel.
PDRQ Primary DMA Request. DMA request from
primary IDE channel.
SDRQ Secondary DMA Request. DMA request
from secondary IDE channel.
PDACK# Primary DMA Acknowledge. DMA acknoledge to primary IDE channel.
SDACK# Secondary DMA Acknowledge. DMA
acknoledge to secondary IDE channel.
PIOR# Primary I/O Read. Primary channel read.
Active low output.
PIOW# Primary I/O Write. Primary channel write.
Active low output.
SIOR# Secondary I/O Read Secondary channel
read. Active low output.
SIOW# Secondary I/O Write Secondary channel
write. Active low output.
2.2.10 IPC
IRQ_MUX[3:0] Multiplexed Interrupt Request.
These are the ISA bus interrupt signals. They are
to be encoded before connection to the STPC
Consumer using ISACLK and ISACLKX2 as the
input selection strobes.
Note that IRQ8B, which by convention is connected to the RTC, is inverted before being sent to the
interrupt controller, so that it may be connected directly to the IRQ pin of the RTC.
PCI_INT[3:0] PCI Interrupt Request. These are
the PCI bus interrupt signals. They are to be en-
DACK_ENC[2:0] DMA Acknowledge. These are
the ISA bus DMA acknowledge signals. They are
encoded by the STPC Consumer before output
and should be decoded externally using ISACLK
and ISACLKX2 as the control strobes.
TC ISA Terminal Count. This is the terminal count
output of the DMA controller and is connected to
the TC line of the ISA bus. It is asserted during the
last DMA transfer, when the byte count expires.
SPKRD Speaker Drive. This the output to the
speaker and is AND of the counter 2 output with
bit 1 of Port 61, and drives an external speaker
driver. This output should be connected to 7407
type high voltage driver.
2.2.11 X-Bus Interface pins / IDE Data
RMRTCCS# / DD[15] ROM/Real Time clock chip
select. This pin is a multi-function pin. When
ISAOE# is active, this signal is used as RMRTCCS#. This signal is asserted if a ROM access
is decoded during a memory cycle. It should be
combined with MEMR# or MEMW# signals to
properly access the ROM. During a IO cycle, this
signal is asserted if access to the Real Time Clock
(RTC) is decoded. It should be combined with IOR
or IOW# signals to properly access the real time
clock.
When ISAOE# is inactive, this signal is used as
IDE DD[15] signal.
This signal must be ORed externally with ISAOE#
and is then connected to ROM and RTC. An
LS244 or equivalent function can be used if OE# is
connected to ISAOE# and the output is provided
with a weak pull-up resistor.
KBCS# / DD[14] Keyboard Chip Select. This pin
is a multi-function pin. When ISAOE# is active,
this signal is used as KBCS#. This signal is asserted if a keyboard access is decoded during a I/O
cycle.
When ISAOE# is inactive, this signal is used as
IDE DD[14] signal.
This signal must be ORed externally with ISAOE#
and is then connected to keyboard. An LS244 or
equivalent function can be used if OE# is connect-
19/51
Issue 1.2
PIN DESCRIPTION
ed to ISAOE# and the output is provided with a
weak pull-up resistor.
RTCRW# / DD[13] Real Time Clock RW. This pin
is a multi-function pin. When ISAOE# is active,
this signal is used as RTCRW#. This signal is asserted for any I/O write to port 71H.
When ISAOE# is inactive, this signal is used as
IDE DD[13] signal.
This signal must be ORed externally with ISAOE#
and then connected to the RTC. An LS244 or
equivalent function can be used if OE is connected to ISAOE# and the output is provided with a
weak pull-up resistor.
RTCDS# / DD[12] Real Time Clock DS. This pin is
a multi-function pin. When ISAOE# is active, this
signal is used as RTCDS. This signal is asserted
for any I/O read to port 71H.
When ISAOE# is inactive, this signal is used as
IDE DD[12] signal.
This signal must be ORed externally with ISAOE#
and is then connected to RTC. An LS244 or equivalent function can be used if OE# is connected to
ISAOE# and the output is provided with a weak
pull-up resistor.
RTCAS# Real time clock address strobe. This signal is asserted for any I/O write to port 70H.
2.2.12 Monitor Interface
RED, GREEN, BLUE RGB Video Outputs. These
are the 3 analog color outputs from the RAMDACs
VSYNC Vertical Synchronisation Pulse. This is
the vertical synchronization signal from the VGA
controller.
20/51
Issue 1.2
HSYNC Horizontal Synchronisation Pulse. This is
the horizontal synchronization signal from the
VGA controller.
VREF_DAC DAC Voltage reference. An external
voltage reference is connected to this pin to bias
the DAC.
RSET Resistor Current Set. This is reference current input to the RAMDAC is used to set the fullscale output of the RAMDAC.
COMP Compensation. This is the RAMDAC compensation pin. Normally, an external capacitor
(typically 10nF) is connected between this pin and
VDD to damp oscillations.
DDC[1:0] Direct Data Channel Serial Link. These
bidirectional pins are connected to CRTC register
3Fh to implement DDC capabilities. They conform
to I2C electrical specifications, they have opencollector output drivers which are internally connected to VDD through pull-up resistors.
They can instead be used for accessing I C devices on board. DDC1 and DDC0 correspond to SCL
and SDA respectively.
COL_CMP Color Compare Output. Allows access
to the video signal which flags when there is a
color compare hit. This signal is multiplexed with
SMEMEW# on the ISA Bus. The signal is selected
by setting Strap Option MD[0] as described in Section 3.
2.2.13 MISCELLANEOUS
SCAN_ENABLE Reserved . The pins are reserved for Test and Miscellaneous functions)
PIN DESCRIPTION
Table 2-3. Pinout.
Pin #
AF3
A3
C4
G23
F25
AF15
AF9
AD15
AF16
AC15
AE17
AD16
AF17
AC17
AE18
AD17
AF18
AE19
AF19
AD18
AE20
AC19
AF20
AE21
AC20
AF21
AD20
Pin name
SYSRSTI
XTALI
XTALO
HCLK
DEV_CLK
GCLK2X
DCLK
MA[0]
MA[1]
MA[2]
MA[3]
MA[4]
MA[5]
MA[6]
MA[7]
MA[8]
MA[9]
MA[10]
MA[11]
RAS#[0]
RAS#[1]
RAS#[2]
RAS#[3]
CAS#[0]
CAS#[1]
CAS#[2]
CAS#[3]
AE22
AF22
AD21
AE23
AC22
AF23
AE24
AF24
AD25
AC25
AC26
AB24
AA25
AA24
Y25
Y24
V23
W24
V26
V24
U23
CAS#[4]
CAS#[5]
CAS#[6]
CAS#[7]
MWE#
MD[0]
MD[1]
MD[2]
MD[3]
MD[4]
MD[5]
MD[6]
MD[7]
MD[8]
MD[9]
MD[10]
MD[11]
MD[12]
MD[13]
MD[14]
MD[15]
Pin #
U24
R26
P25
P26
N25
N26
M25
M26
M24
M23
L24
J25
J26
H26
G25
G26
AD22
AD23
AE26
AD26
AC24
Pin name
MD[16]
MD[17]
MD[18]
MD[19]
MD[20]
MD[21]
MD[22]
MD[23]
MD[24]
MD[25]
MD[26]
MD[27]
MD[28]
MD[29]
MD[30]
MD[31]
MD[32]
MD[33]
MD[34]
MD[35]
MD[36]
Pin #
D25
A20
C20
B19
A19
C19
B18
A18
B17
C18
A17
D17
B16
C17
B15
A15
C16
D15
A14
C15
B13
Pin name
PCI_CLKO
AD[0]
AD[1]
AD[2]
AD[3]
AD[4]
AD[5]
AD[6]
AD[7]
AD[8]
AD[9]
AD[10]
AD[11]
AD[12]
AD[13]
AD[14]
AD[15]
AD[16]
AD[17]
AD[18]
AD[19]
AB25
AB26
Y23
AA26
Y26
W25
W26
V25
U25
U26
T25
R25
T24
R23
R24
N23
P24
N24
L25
L26
K25
K26
K24
H25
J24
H23
H24
F24
MD[37]
MD[38]
MD[39]
MD[40]
MD[41]
MD[42]
MD[43]
MD[44]
MD[45]
MD[46]
MD[47]
MD[48]
MD[49]
MD[50]
MD[51]
MD[52]
MD[53]
MD[54]
MD[55]
MD[56]
MD[57]
MD[58]
MD[59]
MD[60]
MD[61]
MD[62]
MD[63]
PCI_CLKI
D13
A13
C14
C13
A12
B11
C12
A11
D12
B10
C11
A10
D10
C10
A9
B8
A8
B7
D8
A7
C8
B6
D7
A6
C21
A21
B20
C22
AD[20]
AD[21]
AD[22]
AD[23]
AD[24]
AD[25]
AD[26]
AD[27]
AD[28]
AD[29]
AD[30]
AD[31]
CBE[0]
CBE[1]
CBE[2]
CBE[3]
FRAME#
TRDY#
IRDY#
STOP#
DEVSEL#
PAR
SERR#
LOCK#
PCI_REQ#[0]
PCI_REQ#[1]
PCI_REQ#[2]
PCI_GNT#[0]
21/51
Issue 1.2
PIN DESCRIPTION
Pin #
B21
D20
A5
C6
B4
D5
Pin name
PCI_GNT#[1]
PCI_GNT#[2]
PCI_INT[0]
PCI_INT[1]
PCI_INT[2]
PCI_INT[3]
F2
G4
F3
F1
G2
G3
H2
J4
H1
H3
J2
J1
K2
J3
LA[17]/DA[0]
LA[18]/DA[1]
LA[19]/DA[2]
LA[20]/PCS1#
LA[21]/PCS3#
LA[22]/SCS1#
LA[23]/SCS3#
SA[0]
SA[1]
SA[2]
SA[3]
SA[4]
SA[5]
SA[6]
K1
K4
L2
K3
L1
M2
M1
L3
N2
M4
N1
M3
P4
P3
R2
N3
P1
R1
T2
R3
T1
R4
U2
T3
U1
U4
V2
U3
SA[7]
SA[8]/DD[0]
SA[9]/DD[1]
SA[10]/DD[2]
SA[11]/DD[3]
SA[12] / DD[4]
SA[13] / DD[5]
SA[14] / DD[6]
SA[15] / DD[7]
SA[16] / DD[8]
SA[17] / DD[9]
SA[18] / DD[10]
SA[19] / DD[11]
RTCDS / DD[12]
RTCRW# / DD[13]
KBCS# / DD[14]
RMRTCCS# / DD[15]
SD[0]
SD[1]
SD[2]
SD[3]
SD[4]
SD[5]
SD[6]
SD[7]
SD[8]
SD[9]
SD[10]
Pin #
V1
W2
W1
V3
Y2
Pin name
SD[11]
SD[12]
SD[13]
SD[14]
SD[15]
Y1
IOCHRDY
AE4
AD4
AE5
AF8
W3
AC9
AA2
Y4
AA1
Y3
AB2
AA3
AC2
SYSRSTO#
ISA_CLK
ISA_CLK2X
OSC14M
ALE
ZWS#
BHE#
MEMR#
MEMW#
SMEMR#
SMEMW#/COL_CMP
IOR#
IOW#
AB4
AC1
AB3
AD2
AC3
AD1
AF2
A4
AE3
MASTER#
MCS16#
IOCS16#
REF#
AEN
IOCHCK#
ISAOE#
RTCAS#
GPIOCS#
B1
C2
C1
D2
D3
D1
E2
E4
E3
E1
PIRQ
SIRQ
PDRQ
SDRQ
PDACK#
SDACK#
PIOR#
PIOW#
SIOR#
SIOW#
E23
D26
E24
C25
A24
B23
C23
IRQ_MUX[0]
IRQ_MUX[1]
IRQ_MUX[2]
IRQ_MUX[3]
DREQ_MUX[0]
DREQ_MUX[1]
DACK_ENC[0]
22/51
Issue 1.2
Pin #
A23
B22
D22
C5
Pin name
DACK_ENC[1]
DACK_ENC[2]
TC
SPKRD
AE6
AD6
AF6
AD5
AC5
AD7
AE8
AF5
C7
B5
RED
GREEN
BLUE
VSYNC
HSYNC
VREF_DAC
RSET
COMP
SDA / DDC[0]
SCL / DDC[1]
AC12
AE13
AD14
AD12
AE14
VCLK
VIN[0]
VIN[1]
VIN[2]
VIN[3]
AC14
AF14
AD13
AE15
VIN[4]
VIN[5]
VIN[6]
VIN[7]
AF10
AC10
AF11
AE10
AD9
AD11
AD8
AE9
AE11
AD10
RED_TV
GREEN_TV
BLUE_TV
VCS
ODD_EVEN
CVBS
IREF1_TV
VREF1_TV
IREF2_TV
VREF2_TV
B3
SCAN_ENABLE
AF12
AC7
AF4
AD19
AF13
F26
G24
A16
B12
B9
VDDA_TV
VDD_DAC1
VDD_DAC2
VDD_GCLK_PLL
VDD_DCLK_PLL
VDD_HCLK_PLL
VDD_DEVCLK_PLL
VDD5
VDD5
VDD5
PIN DESCRIPTION
Pin #
D18
A22
B14
C9
D6
D11
D16
D21
F4
F23
G1
K23
L4
L23
P2
T4
T23
T26
W4
AA4
AA23
VDD5
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
VDD
Pin name
AB1
AB23
AC6
AC11
AC16
AC21
VDD
VDD
VDD
VDD
VDD
VDD
AE12
AE7
AF7
E25
E26
A1:2
A26
B2
B25:26
C3
C24
D4
D9
D14
D19
D23
H4
J23
L11:16
M11:16
N4
VSSA_TV
VSS_DAC1
VSS_DAC2
VSS_DLL
VSS_DLL
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
Pin #
N11:16
P11:16
P23
R11:16
T11:16
V4
W23
AC4
AC8
AC13
AC18
AC23
AD3
AD24
AE1:2
AE16
AE25
AF1
AF25
AF26
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
Pin name
C26
D24
B24
A25
RESERVED
RESERVED
RESERVED
RESERVED
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Issue 1.2
PIN DESCRIPTION
24/51
Issue 1.2
Update History for Pin Description chapter
2.4 Update History for Pin Description chapter
The following changes have been made to the Pin Description Chapter on 08/02/2000
Section
2.2
Change
Added
Text
Color Compare Signal
The following changes have been made to the Pin Description Chapter on 13/01/2000
Section
2.2
Change
Added
Text
“to a minimum of 8MHz”
25/51
Issue 1.2
Update History for Pin Description chapter
26/51
Issue 1.2
STRAP OPTION
3. STRAP OPTION
This chapter defines the STPC Consumer Strap
Options and their location
Memory
Data
Note
Lines
MD0
1
MD1
MD2
2
MD3
2
MD4
2
MD5
2
MD6
2
MD7
MD8
MD9
MD10
MD11
MD12
MD13
MD14
MD15
MD16
MD17
MD18
MD19
MD20
MD21
MD22
MD23
MD24
MD25
MD26
MD27
MD28
MD29
MD30
MD31
MD32
MD33
MD34
MD35
MD36
MD37
2
2
2
2
2
2
2
2
2
Refer to
Designation
Location
Actual
Settings
Set to ’0’
Set to ’1’
Index 4A, Bit 0
Index 4A, bit 2
Index 4A, bit 3
Index 4A,bit 4
Index 4A,bit 5
Index 4A,bit 6
User defined COLOR_KEY
User defined
70 ns
Pull up
User defined
EDO
User defined
70 ns
Pull up
-
SMEMW#
60 ns
PCI Clock
HCLK
Type
Reserved
Reserved
Speed
Speed
Type
Speed
Speed
Type
Reserved
PCI_CLKO Divisor
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
HCLK PLL Speed
Index 4A, bit 7
Index4B,bit0
Index4B,bit1
Index 4B,bit 2
Index 4B,bit 3
Index 4B,bit 4
Index 4B,bit 5
Index 4B, bit 6
Index 4B,bit 7
Index 4C,bit 0
Index 4C,bit 1
Index 4C,bit 2
Index 4C,bit 3
Index 4C, bit4
Index 5F, bit 0
Index 5F, bit 1
Index 5F,bit 2
Index 5F,bit 3
Index 5F,bit 4
Index 5F,bit 5
-
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
-
User defined
Pull up
User defined
Pull up
User defined
User defined
Pull up
User defined
Pull up
User defined
Pull up
Pull up
Pull up
Pull up
Pull up
Pull up
User defined
User defined
User defined
User defined
User defined
User defined
User defined
User defined
Pull down
Pull down
Pull down
Pull down
Pull down
Pull down
Pull down
Pull down
Pull down
Pull up
Pull up
FPM
60 ns
FPM
60 ns
FPM
HCLK / 3
25 MHz
33 MHz
40 MHz
50 MHz
60 MHz
66 MHz
75 MHz
80 MHz
-
DRAM Bank 1
DRAM Bank 0
DRAM Bank 3
DRAM Bank 2
Reserved
Speed
Speed
Type
Speed
Speed
EDO
70 ns
EDO
70 ns
EDO
HCLK / 2
000
001
010
011
100
101
110
111
-
FPM
60 ns
-
27/51
Issue 1.2
STRAP OPTION
Memory
Data
Note
Lines
MD38
MD39
MD40
MD41
MD42
MD43
Refer to
Designation
CPU
-
Reserved
Reserved
CPU Mode
Reserved
Reserved
Reserved
Note;
1) This Strap Option selects between two different
functional blocks, the first is the ISA (SMEMW#)
and the other is the VGA block (Color_Key).
2) Setting of Strap Options MD [2:15] have no effect on the DRAM Controller but are purely meant
for software issues. i.e. Readable in a register.
3.1 STRAP REGISTER DESCRIPTION
3.1.1 STRAP
(STRAP0)
REGISTER
0
INDEX
4AH
Bits 7-0 of this register reflect the status of pins
MD[7:0] respectively. They are expected to be
connected on the system board to the SIMM configuration pins as follows:
Bit Sampled
Bit 7
Bits 6-5
Bit 4
Bits 3-2
Bits 1-0
Actual
Settings
Location
Description
SIMM 0 dram type
SIMM 0 speed
SIMM 1 dram type
SIMM 1 speed
Reserved
-
Set to ’0’
Pull up
Pull up
User defined
Pull down
Pull up
Pull down
3.1.2 STRAP
(STRAP1)
Set to ’1’
DX1
-
REGISTER
1
DX2
-
INDEX
4BH
Bits 7-0 of this register reflect the status of pins
MD[15:8] respectively. They are expected to be
connected on the system board to the SIMM configuration pins as follows:
Bit Sampled
Bit 7
Bits 6-5
Bit 4
Bits 3-2
Description
SIMM 2 dram type
SIMM 2 speed
SIMM 3 dram type
SIMM 3 speed
Note that the SIMM speed and type information
read here is meant only for thesoftware and is not
used by the hardware. The software must program the Host and graphics dram controller configuration registers appropriately based on these
bits.
This register defaults to the values sampled on
MD[15:8] pins after reset.
3.1.3 STRAP
(STRAP2)
REGISTER
2
INDEX
4CH
Note that the SIMM speed and type information
read here is meant only for the software and is not
used by the hardware. The software must program the Host and graphics dram controller configuration registers appropriately based on these
bits.
Bits 4-0 of this register reflect the status of pins
MD[20:16] respectively. Bit 5 of this register reflect
the status of pin MD[23]. Bit 4 is writeable, writes
to other bits in this register have no effect.
This register defaults to the values sampled on
MD[7:0] pins after reset.
Bit 4-2; Reserved
28/51
Issue 1.2
They are use by the chip as follows:
STRAP OPTION
Bit 1 This bit reflects the value sampled on
MD[17] pin and controls the PCI clock output as
follows:
Bits 5-3; These pins reflect the value sampled on
MD[26:24] pins respectively and control the Host
clock frequency synthesizer.
0: PCI clock output = HCLK / 2
Bit 2-0; Reserved
1: PCI clock output = HCLK / 3
This register defaults to the values sampled on
above pins after reset.
Bit 0; Reserved
Strap Options [39:27] are reserved.
This register defaults to the values sampled on
MD[23] & MD[20:16] pins after reset.
3.1.4 HCLK PLL STRAP REGISTER 0 INDEX
5FH (HCLK_STRAP0)
Bits 5-0 of this register reflect the status of pins
MD[26:21] respectively. They are use by the chip
as follows:
3.1.5 486 CLOCK PROGRAMMING (486_CLK)
The bit MD[40] is used to set the clock multiplication factor of the 486 core. With the MD[40] pin
pulled low the 486 will run in DX (x1) mode, while
with the MD[40] pin pulled high the 486 will run in
DX2 (x2) mode. The default value of the resistor
on this strap input should be a resister to ground
(DX mode).
Strap options MD[43:41] are reserved.
29/51
Issue 1.2
ELECTRICAL SPECIFICATIONS
4. ELECTRICAL SPECIFICATIONS
4.1 Introduction
20 kΩ (±10%) pull-up resistor to prevent spurious
operation.
The electrical specifications in this chapter are valid for the STPC Consumer.
4.2 Electrical Connections
4.2.1 Power/Ground Connections/Decoupling
Due to the high frequency of operation of the
STPC Consumer, it is necessary to install and test
this device using standard high frequency techniques. The high clock frequencies used in the
STPC Consumer and its output buffer circuits can
cause transient power surges when several output
buffers switch output levels simultaneously. These
effects can be minimized by filtering the DC power
leads with low-inductance decoupling capacitors,
using low impedance wiring, and by utilizing all of
the VSS and VDD pins.
4.2.2 Unused Input Pins
All inputs not used by the designer and not listed
in the table of pin connections in Chapter 3 should
be connected either to VDD or to VSS. Connect
active-high inputs to VDD through a 20 kΩ (±10%)
pull-down resistor and active-low inputs to VSS
and connect active-low inputs to VCC through a
4.2.3 Reserved Designated Pins
Pins designated reserved should be left disconnected. Connecting a reserved pin to a pull-up resistor, pull-down resistor, or an active signal could
cause unexpected results and possible circuit
malfunctions.
4.3 Absolute Maximum Ratings
The following table lists the absolute maximum
ratings for the STPC Consumer device. Stresses
beyond those listed under Table 4-1 limits may
cause permanent damage to the device. These
are stress ratings only and do not imply that operation under any conditions other than those specified in section ”Operating Conditions”.
Exposure to conditions beyond Table 4-1 may (1)
reduce device reliability and (2) result in premature failure even when there is no immediately apparent sign of failure. Prolonged exposure to conditions at or near the absolute maximum ratings
(Table 4-1) may also result in reduced useful life
and reliability.
Table 4-1. Absolute Maximum Ratings
Symbol
VDDx
VI , VO
TSTG
TOPER
PTOT
Parameter
DC Supply Voltage
Digital Input and Output Voltage
Storage Temperature
Operating Temperature
Total Power Dissipation
30/51
Issue 1.2
Value
-0.3, 4.0
-0.3, VDD + 0.3
Units
V
V
-40, +150
0, +70
4.8
°C
°C
W
ELECTRICAL SPECIFICATIONS
4.4 DC Characteristics
Table 4-2. DC Characteristics
Recommended Operating conditions : VDD = 3.3V
Symbol
VDD
PDD
H CLK
VREF_D
Parameter
Operating Voltage
Supply Power
Internal Clock
±0.3V, Tcase = 0 to 100°C unless otherwise specified
Test conditio ns
Min
3.0
Typ
3.3
3.2
Max
3.6
3.9
75
Unit
V
W
Mhz
1.215
1.235
1.255
V
0.5
V
V
V
V
V
V
µA
pF
pF
pF
VDD = 3.3V, HCLK = 66Mhz
(Note 1)
DAC Voltage Reference
AC
VOL
VOH
VIL
Output Low Voltage
Output High Voltage
Input Low Voltage
VIH
Input High Voltage
ILK
C IN
C OUT
C CLK
Input Leakage Current
Input Capacitance
Output Capacitance
Clock Capacitance
ILoad =1.5 to 8mA depending of the pin
ILoad =-0.5 to -8mA depending of the pin
Except XTALI
XTALI
Except XTALI
XTALI
Input, I/O
(Note 2)
(Note 2)
(Note 2)
2.4
-0.3
-0.3
2.1
2.35
-5
0.8
0.9
VDD+0.3
VDD+0.3
5
rising clock edge reference level VREF , and other
reference levels are shown in Table 4-3 below for
the STPC Consumer. Input or output signals must
cross these levels during testing.
Notes:
1. MHz ratings refer to CPU clock frequency.
2. Not 100% tested.
4.5 AC Characteristics
Table 4-4 through Table 4-9 list the AC characteristics including output delays, input setup requirements, input hold requirements and output float
delays. These measurements are based on the
measurement points identified in Figure 4-1 . The
Figure 4-1 shows output delay (A and B) and input
setup and hold times (C and D). Input setup and
hold times (C and D) are specified minimums, defining the smallest acceptable sampling window a
synchronous input signal must be stable for correct operation.
Table 4-3. Drive Level and Measurement Points for Switching Characteristics
Symbol
VREF
VIHD
V ILD
Value
1.5
3.0
0.0
Units
V
V
V
Note: Refer to Figure 4-1.
31/51
Issue 1.2
ELECTRICAL SPECIFICATIONS
Figure 4-1 Drive Level and Measurement Points for Switching Characteristics
Tx
VIHD
VRef
CLK:
VILD
A
B
MAX
MIN
Valid
Output n
OUTPUTS:
Valid
Output n+1
VRef
C
D
VIHD
Valid
INPUTS:
VRef
Input
VILD
LEGEND:
A
B
C
D
- Maximum Output Delay Specification
- Minimum Output Delay Specification
- Minimum Input Setup Specification
- Minimum Input Hold Specification
Figure 4-2 CLK Timing Measurement Points
T1
T2
VIH (MIN)
VRef
CLK
VIL (MAX)
T5
T3
T4
T1 - One Clock Cycle
T2 - Minimum Time at VIH
T3 - Minimum Time at VIL
T4 - Clock Fall Time
T5 - Clock Rise Time
NOTE; All sIgnals are sampled on the rising edge of the CLK.
LEGEND:
Note; The above timings are generic timings and are not specific to the interfaces defined below
32/51
Issue 1.2
ELECTRICAL SPECIFICATIONS
4.5.1 AC Timing parameters
Table 4-4. PCI Bus AC Timing
Name
t1
t2
t3
t4
t5
T6
T7
T8
T9
t10
t11
t12
t13
t14
t15
t16
t17
t18
t19
Parameter
PCI_CLKI to AD[31:0] valid
PCI_CLKI to FRAME# valid
PCI_CLKI to CBE#[3:0] valid
PCI_CLKI to PAR valid
PCI_CLKI to TRDY# valid
PCI_CLKI to IRDY# valid
PCI_CLKI to STOP# valid
PCI_CLKI to DEVSEL# valid
PCI_CLKI to PCI_GNT# valid
AD[31:0] bus setup to PCI_CLKI
Min
2
2
2
2
2
2
2
2
2
7
AD[31:0] bus hold from PCI_CLKI
PCI_REQ#[2:0] setup to PCI_CLKI
PCI_REQ#[2:0] hold from PCI_CLKI
CBE#[3:0] setup to PCI_CLKI
CBE#[3:0] hold to PCI_CLKI
IRDY# setup to PCI_CLKI
IRDY# hold to PCI_CLKI
FRAME# setup to PCI_CLKI
FRAME# hold from PCI_CLKI
Max
11
11
11
11
11
11
11
11
12
0
7
4
7
0
7
0
7
0
Unit
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Table 4-5. DRAM Bus AC Timing
Name
t22
t23
t24
t25
t26
t27
t28
t29
t30
t31
t32
t33
Parameter
HCLK to RAS#[3:0] valid
HCLK to CAS#[7:0] bus valid
HCLK to MA[11:0] bus valid
HCLK to MWE# valid
HCLK to MD[63:0] bus valid
MD[63:0] Generic setup
GCLK2X to RAS#[3:0] valid
GCLK2X to CAS#[7:0] valid
GCLK2X to MA[11:0] bus valid
GCLK2X to MWE# valid
GCLK2X to MD[63:0] bus valid
MD[63:0] Generic hold
Min
Max
19
19
19
17
20
13
19
19
19
17
20
0
Unit
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Table 4-6. IDE Bus AC Timing
Name
t20
t21
Parameter
DD[15:0] setup to PIOR#/SIOR# falling
DD[15:0} hold to PIOR#/SIOR# falling
Min
15
0
Max
Unit
ns
ns
33/51
Issue 1.2
ELECTRICAL SPECIFICATIONS
Table 4-7. Video Input AC Timing
Name
t35
t36
t37
t38
t39
t40
t41
t42
Parameter
VIN[7:0] setup to VCLK
VIN[7:0] hold from VCLK
VCLK to ODD_EVEN valid
VCLK to VCS valid
ODD_EVEN setup to VCLK
ODD_EVEN hold from VCLK
VCS setup to VCLK
VCS hold from VCLK
Min
5
4
Max
15
15
10
5
10
5
Unit
ns
ns
ns
ns
ns
ns
ns
ns
Table 4-8. Graphics Adapter (VGA) AC Timing
Name
t43
t44
Parameter
DCLK to VSYNC valid
DCLK to HSYNC valid
Min
Max
30
30
Unit
ns
ns
Min
Max
60
60
Unit
ns
ns
62
35
28
60
62
50
50
50
50
50
50
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Table 4-9. ISA Bus AC Timing
Name
t45
t46
Parameter
XTALO to LA[23:17] bus active
XTALO to SA[19:0] bus active
t47
t48
t49
t50
t51
t52
t53
t54
t55
t56
t57
XTALO to BHE# valid
XTALO to SD[15:0] bus active
PCI_CLKI to ISAOE# valid
XTALO to GPIOCS# valid
XTALO to ALE valid
XTALO to MEMW# valid
XTALO to MEMR# valid
XTALO to SMEMW# valid
XTALO to SMEMR# valid
XTALO to IOR# valid
XTALO to IOW# valid
34/51
Issue 1.2
Update History for Electrical Specification chapter
4.10 Update History for Electrical Specification chapter
The following changes have been made to the Electrical Specification Chapter on the 07/02/2000.
Section
Change
Text
4.5
Revued
Timings t35 - t42
The following changes have been made to the Electrical Specification Chapter on the 20/10/99.
Section
Change
Text
4.5
Revued
Timings T1-10, T12, T14, T16, T18, T26, T32, T35, T39-42 &T54
The following changes have been made to the Electrical Specification Chapter on the 16/08/99.
Section
18
Change
Text
Removed
Figure 4-2 CLK Timing Measurement Points.
35/51
Issue 1.2
Update History for Electrical Specification chapter
36/51
MECHANICAL DATA
5. MECHANICAL DATA
5.1 388-Pin Package Dimension
Dimensions are shown in Figure 5-2, Table 5-1
and Figure 5-3, Table 5-2.
The pin numbering for the STPC 388-pin Plastic
BGA package is shown in Figure 5-1.
Figure 5-1. 388-Pin PBGA Package - Top View
1
3
2
5
4
7
6
9
8
11
10
13
12
15
14
17
16
19
18
21
20
23
22
25
24
26
A
A
B
C
B
C
D
D
E
F
E
F
G
G
H
H
J
J
K
K
L
L
M
N
M
N
P
P
R
R
T
T
U
U
V
V
W
W
Y
Y
AA
AA
AB
AC
AB
AC
AD
AD
AE
AE
AF
AF
1
3
2
5
4
7
6
9
8
11
10
13
12
15
14
17
16
19
18
21
20
23
22
25
24
26
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Issue 1.2
MECHANICAL DATA
Figure 5-2. 388-pin PBGA Package - PCB Dimensions
A1 Ball Pad Corner
A
B
A
D
E
F
Detail
C G
Table 5-1. 388-pin PBGA Package - PCB Dimensions
Symbols
A
B
C
D
E
F
G
Min
34.95
1.22
0.58
1.57
0.15
0.05
0.75
mm
Typ
35.00
1.27
0.63
1.62
0.20
0.10
0.80
Max
35.05
1.32
0.68
1.67
0.25
0.15
0.85
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Issue 1.2
Min
1.375
0.048
0.023
0.062
0.006
0.002
0.030
inches
Typ
1.378
0.050
0.025
0.064
0.008
0.004
0.032
Max
1.380
0.052
0.027
0.066
0.001
0.006
0.034
MECHANICAL DATA
Figure 5-3. 388-pin PBGA Package - Dimensions
C
F
D
E
Solderball
Solderball after collapse
B
G
A
Table 5-2. 388-pin PBGA Package - Dimensions
Symbols
A
B
C
D
E
F
G
Min
0.50
1.12
0.60
0.52
0.63
0.60
mm
Typ
0.56
1.17
0.76
0.53
0.78
0.63
30.0
Max
0.62
1.22
0.92
0.54
0.93
0.66
Min
0.020
0.044
0.024
0.020
0.025
0.024
inches
Typ
0.022
0.046
0.030
0.021
0.031
0.025
11.8
Max
0.024
0.048
0.036
0.022
0.037
0.026
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Issue 1.2
MECHANICAL DATA
5.2 388-Pin Package thermal data
Structure in shown in Figure 5-4.
388-pin PBGA package has a Power Dissipation
Capability of 4.5W which increases to 6W when
used with a Heatsink.
Thermal dissipation options are illustrated in Figure 5-5 and Figure 5-6.
Figure 5-4. 388-Pin PBGA structure
Signal layers
Power & Ground layers
Thermal balls
Figure 5-5. Thermal dissipation without heatsink
Board
Ambient
Board dimensions:
- 10.2 cm x 12.7 cm
- 4 layers (2 for signals, 1 GND, 1VCC)
Junction
Rca
Case
6
Rjc
Junction
6
Board
Case
8.5
125
Rjb
Board
Rba
Ambient
Ambient
Rja = 13 °C/W
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Issue 1.2
The PBGA is centered on board
There are no other devices
1 via pad per ground ball (8-mil wire)
40% copper on signal layers
Copper thickness:
- 17µm for internal layers
- 34µm for external layers
Airflow = 0
Board temperature taken at the center balls
MECHANICAL DATA
Figure 5-6. Thermal dissipation with heatsink
Board
Ambient
Board dimensions:
- 10.2 cm x 12.7 cm
- 4 layers (2 for signals, 1 GND, 1VCC)
Junction
Rca
Case
3
Rjc
Junction
6
Board
Case
8.5
50
Rjb
Board
Rba
The PBGA is centered on board
There are no other devices
1 via pad per ground ball (8-mil wire)
40% copper on signal layers
Copper thickness:
- 17µm for internal layers
- 34µm for external layers
Ambient
Ambient
Rja = 9.5 °C/W
Airflow = 0
Board temperature taken at the center balls
Heat sink is 11.1°C/W
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Issue 1.2
MECHANICAL DATA
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Issue 1.2
BOARD LAYOUT
6. BOARD LAYOUT
6.1 THERMAL DISSIPATION
Thermal dissipation of the STPC depends mainly
on supply voltage. As a result, when the system
does not need to work at 3.3V, it may be to reduce
the voltage to 3.15V for example. This may save
few 100’s of mW.
The second area that can be concidered is unused interfaces and functions. Depending on the
application, some input signals can be grounded,
and some blocks not powered or shutdown. Clock
speed dynamic adjustment is also a solution that
can be used along with the integrated power management unit.
The standard way to route thermal balls to internal
ground layer implements only one via pad for each
ball pad, connected using a 8-mil wire.
With such configuration the Plastic BGA 388 package dissipates 90% of the heat through the ground
balls, and especially the central thermal balls
which are directly connected to the die, the remaining 10% is dissipated through the case. Adding a heat sink reduces this value to 85%.
As a result, some basic rules have to be applied
when routing the STPC in order to avoid thermal
problems.
First of all, the whole ground layer acts as a heat
sink and ground balls must be directly connected
to it as illustrated in Figure 6-1.
If one ground layer is not enough, a second
ground plane may be added on the solder side.
Figure 6-1. Ground routing
Pad for ground ball
Thru hole to ground layer
Top L
ayer
: Sign
Grou
als
nd la
yer
Powe
r laye
r
Botto
mLa
yer :
signa
ls + l
ocal g
round
layer
(if ne
eded
)
Note: For better visibility, ground balls are not all routed.
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Issue 1.2
BOARD LAYOUT
When considering thermal dissipation, the most
important - and not the more obvious - part of the
layout is the connection between the ground balls
and the ground layer.
To avoid solder wicking over to the via pads during
soldering, it is important to have a solder mask of
4 mil around the pad (NSMD pad), this gives a diameter of 33 mil for a 25 mil ground pad.
A 1-wire connection is shown in Figure 6-2. The
use of a 8-mil wire results in a thermal resistance
of 105°C/W assuming copper is used (418 W/
m.°K). This high value is due to the thickness (34
µm) of the copper on the external side of the PCB.
To obtain the optimum ground layout, place the
vias directly under the ball pads. In this case no local boar d distortion is tolerated.
Considering only the central matrix of 36 thermal
balls and one via for each ball, the global thermal
resistance is 2.9°C/W. This can be easily improved by using four 10 mil wires to connect to the
four vias around the ground pad link as in Figure
6-3. This gives a total of 49 vias and a global resistance for the 36 thermal balls of 0.6°C/W.
The use of a ground plane like in Figure 6-4 is
even better.
The thickness of the copper on PCB layers is typically 34 µm for external layers and 17 µm for internal layers. This means thermal dissipation is not
good and temperature of the board is concentrated around the devices and falls quickly with increased distance.
When it is possible to place a metal layer inside
the PCB, this improves dramatically the heat
spreading and hence thermal dissipation of the
board.
Figure 6-2. Recommended 1-wire ground pad layout
Pad for ground ball (diameter = 25 mil)
Solder Mask (4 mil)
Connection Wire (width = 10 mil)
5
.
34
Via (diameter = 24 mil)
m
il
Hole to ground layer (diameter = 12 mil)
1 mil = 0.0254 mm
Figure 6-3. Recommended 4-wire ground pad layout
4 via pads for each ground ball
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Issue 1.2
BOARD LAYOUT
Figure 6-4. Optimum layout for central ground ball
Clearance = 6mil
External diameter = 37 mil
Via to Ground layer
hole diameter = 14 mil
Solder mask
diameter = 33 mil
Pad for ground ball
diameter = 25 mil
connections = 10 mil
The PBGA Package also dissipates heat through
peripheral ground balls. When a heat sink is
placed on the device, heat is more uniformely
spread throughout the moulding increasing heat
dissipation through the peripheral ground balls.
The more via pads are connected to each ground
ball, the more heat is dissipated . The only limitation is the risk of lossing routing channels.
Figure 6-5 shows a routing with a good trade off
between thermal dissipation and number of routing channels.
Figure 6-5. Global ground layout for good thermal dissipation
Via to ground layer
Ground pad
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Issue 1.2
BOARD LAYOUT
Figure 6-6. Bottom side layout and decoupling
Ground plane for thermal dissipation
Via to ground layer
A local ground plane on opposite side of the board
as shown in Figure 6-6 improves thermal dissipation. It is used to connect decoupling capacitances
but can also be used for connection to a heat sink
or to the system’s metal box for better dissipation.
This possibility of using the whole system’s box for
thermal dissipation is very usefull in case of high
temperature inside the system and low temperature outside. In that case, both sides of the PBGA
should be thermally connected to the metal chassis in order to propagate the heat through the metal. Figure 6-7 illustrates such an implementation.
Figure 6-7. Use of metal plate for thermal dissipation
Die
Board
Metal planes
Thermal conductor
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Issue 1.2
BOARD LAYOUT
6.2 HIGH SPEED SIGNALS
Some Interfaces of the STPC run at high speed
and have to be carefully routed or even shielded.
Here is the list of these interfaces, in decreasing
speed order:
All the clocks have to be routed first and shielded
for speeds of 27MHz or more. The high speed signals have the same contrainsts as some of the
memory interface control signals.
The next interfaces to be routed are Memory, Video/graphics, and PCI.
- Memory Interface.
- Graphics and video interfaces
- PCI bus
All the analog noise sensitive signals have to be
routed in a separate area and hence can be routed indepedently.
- 14MHz oscillator stage
Figure 6-8. Shielding signals
ground ring
shielded signal line
ground pad
ground pad
shielded signal lines
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Issue 1.2
ORDERING DATA
7. ORDERING DATA
7.1 Ordering Codes
ST
PC
STMicroelectronics
Prefix
Product Family
PC: PC Compatible
Product ID
C01: Consumer
Core Speed
66: 66MHz
75: 75MHz
80: 80MHz
10: 100MHz
Package
BT: 388 Overmoulded BGA
Temperature Range
C: Commercial
0 to +70°C
Tcase = 0 to +100°C
I: Industrial
-40 to +85°C
Tcase = -40 to +100°C
Operating Voltage
3 : 3.3V ± 0.3V
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Issue 1.2
C01
66
BT
C
3
ORDERING DATA
7.2 Available Part Numbers
Part Number
STPCC0166BTC3
STPCC0180BTC3
STPCC0110BTC3
STPCC0166BTI3
STPCC0180BTI3
Core Frequency
(MHz)
66
80
100
66
80
CPU Mode
DX
DX
DX2
DX
DX
Tcase Range
(C)
Operating Voltage
(V)
0°C to +100°C
3.3V ± 0.3V
-40°C to +100°C
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ORDERING DATA
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Issue 1.2
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