ETC W83977TF(EOL)

W83977TF
WINBOND I/O
W83977TF Data Sheet Revision History
Pages
Dates
Versi
on
Version
Main Contents
on Web
1
n.a.
05/20/97
0.50
First published.
2
IV,V,6,7,14,49,5 07/01/97
5,69-80,87-96,
103,113, 117,
118,122, 128,
149
III,3,68,134,
07/20/97
0.51
Typo correction and data calibrated
0.60
Explanation of OnNow/
functions; Repagenating
3
146,148; 64-67
security
4
P101,101.1,102 11/18/97
0.61
Register correction
5
P1,3,49,62,64,
67,71,73,74,
100,117,119,
120,129
0.62
Typo correction and data calibrated
03/19/98
wake-up
6
7
8
9
10
Please note that all data and specifications are subject to change without notice. All
the trade marks of products and companies mentioned in this data sheet belong to
their respective owners.
LIFE SUPPORT APPLICATIONS
These products are not designed for use in life support appliances, devices, or
systems where malfunction of these products can reasonably be expected to result
in personal injury. Winbond customers using or selling these products for use in such
applications do so at their own risk and agree to fully indemnify Winbond for any
damages resulting from such improper use or sales.
W83977TF
TABLE OF CONTENTS
GENERAL DESCRIPTION ....................................................................................................... 1
FEATURES.................................................................................................................................... 2
PIN CONFIGURATION ............................................................................................................. 4
1. PIN DESCRIPTION................................................................................................................ 5
1.1
HOST INTERFACE .....................................................................................................................................5
1.2
GENERAL PURPOSE I/O PORT...............................................................................................................7
1.3
SERIAL PORT INTERFACE......................................................................................................................8
1.4
INFRARED INTERFACE ...........................................................................................................................9
1.5
MULTI-MODE PARALLEL PORT ...........................................................................................................9
1.6
FDC INTERFACE ......................................................................................................................................14
1.7
KBC INTERFACE......................................................................................................................................15
1.8
POWER PINS .............................................................................................................................................16
1.9
ACPI INTERFACE.....................................................................................................................................16
2. FDC FUNCTIONAL DESCRIPTION ................................................................................ 17
2.1
W83977TF FDC .........................................................................................................................................17
2.1.1 AT INTERFACE.............................................................................................................................17
2.1.2 FIFO (DATA) ..................................................................................................................................17
2.1.3 DATA SEPARATOR .....................................................................................................................18
2.1.4 WRITE PRECOMPENSATION ...................................................................................................18
2.1.5 PERPENDICULAR RECORDING MODE .................................................................................18
2.1.6 FDC CORE ......................................................................................................................................19
2.1.7 FDC COMMANDS ........................................................................................................................19
2.2
REGISTER DESCRIPTIONS ...................................................................................................................29
2.2.1 STATUS REGISTER A (SA REGISTER) (READ BASE ADDRESS + 0).............................29
2.2.2 STATUS REGISTER B (SB REGISTER) (READ BASE ADDRESS + 1) .............................31
2.2.3 DIGITAL OUTPUT REGISTER (DO REGISTER) (WRITE BASE ADDRESS + 2)............33
2.2.4 TAPE DRIVE REGISTER (TD REGISTER) (READ BASE ADDRESS + 3) ........................33
2.2.5 MAIN STATUS REGISTER (MS REGISTER) (READ BASE ADDRESS + 4) ....................34
-I-
Publication Release Date: March 1998
Revision 0.62
W83977TF
2.2.6 DATA RATE REGISTER (DR REGISTER) (WRITE BASE ADDRESS + 4) .......................34
2.2.7 FIFO REGISTER (R/W BASE ADDRESS + 5) ..........................................................................36
2.2.8 DIGITAL INPUT REGISTER (DI REGISTER) (READ BASE ADDRESS + 7)....................38
2.2.9 CONFIGURATION CONTROL REGISTER (CC REGISTER)
(WRITE BASE ADDRESS + 7)...................................................................................................39
3. UART PORT............................................................................................................................ 40
3.1
UNIVERSAL ASYNCHRONOUS RECEIVER/TRANSMITTER (UART A, UART B)..................40
3.2
REGISTER ADDRESS..............................................................................................................................40
3.2.1 UART CONTROL REGISTER (UCR) (READ/WRITE)...........................................................40
3.2.2 UART STATUS REGISTER (USR) (READ/WRITE) ...............................................................42
3.2.3 HANDSHAKE CONTROL REGISTER (HCR) (READ/WRITE) ............................................43
3.2.4 HANDSHAKE STATUS REGISTER (HSR) (READ/WRITE).................................................44
3.2.5 UART FIFO CONTROL REGISTER (UFR) (WRITE ONLY) .................................................45
3.2.6 INTERRUPT STATUS REGISTER (ISR) (READ ONLY).......................................................46
3.2.7 INTERRUPT CONTROL REGISTER (ICR) (READ/WRITE).................................................47
3.2.8 PROGRAMMABLE BAUD GENERATOR (BLL/BHL) (READ/WRITE) .............................47
3.2.9 USER-DEFINED REGISTER (UDR) (READ/WRITE).............................................................48
4. INFRARED (IR) PORT ......................................................................................................... 49
5. PARALLEL PORT ............................................................................................................... 49
5.1
PRINTER INTERFACE LOGIC ...............................................................................................................49
5.2
ENHANCED PARALLEL PORT (EPP)..................................................................................................50
5.2.1 DATA SWAPPER ..........................................................................................................................51
5.2.2 PRINTER STATUS BUFFER.......................................................................................................51
5.2.3 PRINTER CONTROL LATCH AND PRINTER CONTROL SWAPPER...............................52
5.2.4 EPP ADDRESS PORT...................................................................................................................52
5.2.5 EPP DATA PORT 0-3....................................................................................................................53
5.2.6 BIT MAP OF PARALLEL PORT AND EPP REGISTERS .......................................................53
5.2.7 EPP PIN DESCRIPTIONS ............................................................................................................54
5.2.8 EPP OPERATION ..........................................................................................................................54
5.3
EXTENDED CAPABILITIES PARALLEL (ECP) PORT .....................................................................55
5.3.1 ECP REGISTER AND MODE DEFINITIONS...........................................................................55
5.3.2 DATA AND ECPAFIFO PORT....................................................................................................56
5.3.3 DEVICE STATUS REGISTER (DSR).........................................................................................56
5.3.4 DEVICE CONTROL REGISTER (DCR) ....................................................................................57
- II -
Publication Release Date: March 1998
Revision 0.62
W83977TF
5.3.5 CFIFO (PARALLEL PORT DATA FIFO) MODE = 010...........................................................58
5.3.6 ECPDFIFO (ECP DATA FIFO) MODE = 011............................................................................58
5.3.7 TFIFO (TEST FIFO MODE) MODE = 110 .................................................................................58
5.3.8 CNFGA (CONFIGURATION REGISTER A) MODE = 111 ....................................................58
5.3.9 CNFGB (CONFIGURATION REGISTER B) MODE = 111.....................................................58
5.3.10 ECR (EXTENDED CONTROL REGISTER) MODE = ALL....................................................59
5.3.11 BIT MAP OF ECP PORT REGISTERS .......................................................................................60
5.3.12 ECP PIN DESCRIPTIONS ............................................................................................................61
5.3.13 ECP OPERATION..........................................................................................................................62
5.3.14 FIFO OPERATION ........................................................................................................................62
5.3.15 DMA TRANSFERS........................................................................................................................63
5.3.16 PROGRAMMED I/O (NON-DMA) MODE................................................................................63
5.4
EXTENSION FDD MODE (EXTFDD)...................................................................................................63
5.5
EXTENSION 2FDD MODE (EXT2FDD) ..............................................................................................63
6. KEYBOARD CONTROLLER .............................................................................................64
6.1
OUTPUT BUFFER ....................................................................................................................................64
6.2
INPUT BUFFER .........................................................................................................................................64
6.3
STATUS REGISTER .................................................................................................................................65
6.4
COMMANDS .............................................................................................................................................65
6.5
HARDWARE GATEA20/KEYBOARD RESET CONTROL LOGIC .................................................67
6.5.1 KB CONTROL REGISTER (LOGIC DEVICE 5, CR-F0) .........................................................67
6.5.2 PORT 92 CONTROL REGISTER (DEFAULT VALUE = 0X24) ............................................67
6.4
ONNOW / SECURITY KEYBOARD AND MOUSE WAKE-UP ......................................................68
7. GENERAL PURPOSE I/O....................................................................................................69
7.1
BASIC I/O FUNCTIONS...........................................................................................................................71
7.2
ALTERNATE I/O FUNCTIONS ..............................................................................................................73
7.2.1 INTERRUPT STEERING..............................................................................................................73
7.2.2 WATCH DOG TIMER OUTPUT .................................................................................................74
7.2.3 POWER LED...................................................................................................................................74
7.2.4 GENERAL PURPOSE ADDRESS DECODER..........................................................................74
7.2.5 GENERAL PURPOSE WRITE STROBE....................................................................................74
8. PLUG AND PLAY CONFIGURATION ............................................................................ 75
8.1
COMPATIBLE PNP...................................................................................................................................75
8.1.1 EXTENDED FUNCTION REGISTERS......................................................................................75
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Publication Release Date: March 1998
Revision 0.62
W83977TF
8.1.2 EXTENDED FUNCTIONS ENABLE REGISTERS (EFERS) .................................................76
8.1.3 EXTENDED FUNCTION INDEX REGISTERS (EFIRS), EXTENDED FUNCTION
DATA REGISTERS(EFDRS) .......................................................................................................76
9. ACPI REGISTERS FEATURES ......................................................................................... 77
9.1
SMI TO SCI/SCI TO SMI AND BUS MASTER ....................................................................................78
9.2
POWER MANAGEMENT TIMER ..........................................................................................................79
9.3
ACPI REGISTERS (ACPIRS)...................................................................................................................80
9.3.1 POWER MANAGEMENT 1 STATUS REGISTER 1 (PM1STS1) ..........................................80
9.3.2 POWER MANAGEMENT 1 STATUS REGISTER 2 (PM1STS2) ..........................................81
9.3.3 POWER MANAGEMENT 1 ENABLE REGISTER 1(PM1EN1) ............................................82
9.3.4 POWER MANAGEMENT 1 ENABLE REGISTER 2 (PM1EN2) ...........................................82
9.3.5 POWER MANAGEMENT 1 CONTROL REGISTER 1 (PM1CTL1)......................................83
9.3.6 POWER MANAGEMENT 1 CONTROL REGISTER 2 (PM1CTL2)......................................83
9.3.7 POWER MANAGEMENT 1 CONTROL REGISTER 3 (PM1CTL3)......................................84
9.3.8 POWER MANAGEMENT 1 CONTROL REGISTER 4 (PM1CTL4)......................................84
9.3.9 POWER MANAGEMENT 1 TIMER 1 (PM1TMR1) ................................................................85
9.3.10 POWER MANAGEMENT 1 TIMER 2 (PM1TMR2) ................................................................85
9.3.11 POWER MANAGEMENT 1 TIMER 3 (PM1TMR3) ................................................................86
9.3.12 POWER MANAGEMENT 1 TIMER 4 (PM1TMR4) ................................................................87
9.3.13 GENERAL PURPOSE EVENT 0 STATUS REGISTER 1 (GP0STS1)...................................87
9.3.14 GENERAL PURPOSE EVENT 0 STATUS REGISTER 2 (GP0STS2)...................................88
9.3.15 GENERAL PURPOSE EVENT 0 ENABLE REGISTER 1 (GP0EN1)....................................89
9.3.16 GENERAL PURPOSE EVENT 0 ENABLE REGISTER 2 (GP0EN2)....................................89
9.3.17 GENERAL PURPOSE EVENT 1 STATUS REGISTER 1 (GP1STS1)...................................90
9.3.18 GENERAL PURPOSE EVENT 1 STATUS REGISTER 2 (GP1STS2)...................................90
9.3.19 GENERAL PURPOSE EVENT 1 ENABLE REGISTER 1 (GP1EN1)....................................91
9.3.20 GENERAL PURPOSE EVENT 1 ENABLE REGISTER 2 (GP1EN2)....................................91
9.3.21 BIT MAP CONFIGURATION REGISTERS...............................................................................92
10. SERIAL IRQ ......................................................................................................................... 93
10.1 START FRAME .........................................................................................................................................94
10.2 IRQ/DATA FRAME...................................................................................................................................94
10.3 STOP FRAME ............................................................................................................................................94
10.4 RESET AND INITIALIZATION ..............................................................................................................95
11. CONFIGURATION REGISTER.......................................................................................96
- IV -
Publication Release Date: March 1998
Revision 0.62
W83977TF
11.1 CHIP (GLOBAL) CONTROL REGISTER ..............................................................................................96
11.2 LOGICAL DEVICE 0 (FDC)...................................................................................................................100
11.3 LOGICAL DEVICE 1 (PARALLEL PORT)..........................................................................................103
11.4 LOGICAL DEVICE 2 (UART A)¢) ........................................................................................................104
11.5 LOGICAL DEVICE 3 (UART B) ...........................................................................................................104
11.6 LOGICAL DEVICE 5 (KBC) ..................................................................................................................106
11.7 LOGICAL DEVICE 7 (GP I/O PORT I).................................................................................................107
11.8 LOGICAL DEVICE 8 (GP I/O PORT II) ...............................................................................................110
11.9 LOGICAL DEVICE 9 (GP I/O PORT III) ..............................................................................................114
11.10 LOGICAL DEVICE A (ACPI) ................................................................................................................117
12. SPECIFICATIONS ............................................................................................................123
12.1 ABSOLUTE MAXIMUM RATINGS ....................................................................................................123
12.2 DC CHARACTERISTICS .......................................................................................................................123
12.3 AC CHARACTERISTICS .......................................................................................................................127
12.3.1 FDC: DATA RATE = 1 MB, 500 KB, 300 KB, 250 KB/SEC...............................................127
12.3.2 UART/PARALLEL PORT........................................................................................................129
12.3.3 PARALLEL PORT MODE PARAMETERS ..........................................................................129
12.3.4 EPP DATA OR ADDRESS READ CYCLE TIMING PARAMETERS..............................130
12.3.5 EPP DATA OR ADDRESS WRITE CYCLE TIMING PARAMETERS ............................131
12.3.6 PARALLEL PORT FIFO TIMING PARAMETERS..............................................................132
12.3.7 ECP PARALLEL PORT FORWARD TIMING PARAMETERS.........................................132
12.3.8 ECP PARALLEL PORT REVERSE TIMING PARAMETERS ...........................................132
12.3.9 KBC TIMING PARAMETERS ................................................................................................133
12.3.10 GPIO TIMING PARAMETERS................................................................................................134
13. TIMING WAVEFORMS ..................................................................................................135
13.1 FDC ............................................................................................................................................................135
13.2 UART/PARALLEL...................................................................................................................................136
13.2.1 MODEM CONTROL TIMING ................................................................................................137
13.3 PARALLEL PORT ...................................................................................................................................138
13.3.1 PARALLEL PORT TIMING.....................................................................................................138
13.3.2 EPP DATA OR ADDRESS READ CYCLE (EPP VERSION 1.9)......................................139
13.3.3 EPP DATA OR ADDRESS WRITE CYCLE (EPP VERSION 1.9) ....................................140
13.3.4 EPP DATA OR ADDRESS READ CYCLE (EPP VERSION 1.7)......................................141
13.3.5 EPP DATA OR ADDRESS WRITE CYCLE (EPP VERSION 1.7) ....................................142
13.3.6 PARALLEL PORT FIFO TIMING...........................................................................................142
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Publication Release Date: March 1998
Revision 0.62
W83977TF
13.3.7 ECP PARALLEL PORT FORWARD TIMING......................................................................143
13.3.8 ECP PARALLEL PORT REVERSE TIMING........................................................................143
13.4 KBC............................................................................................................................................................144
13.4.1 WRITE CYCLE TIMING..........................................................................................................144
13.4.2 READ CYCLE TIMING ...........................................................................................................144
13.4.3 SEND DATA TO K/B...............................................................................................................144
13.4.4 RECEIVE DATA FROM K/B ..................................................................................................145
13.4.5 INPUT CLOCK..........................................................................................................................145
13.4.6 SEND DATA TO MOUSE.......................................................................................................145
13.4.7 RECEIVE DATA FROM MOUSE ..........................................................................................145
13.5 GPIO WRITE TIMING DIAGRAM .......................................................................................................146
13.6 MASTER RESET (MR) TIMING...........................................................................................................146
14. APPLICATION CIRCUITS .............................................................................................147
14.1 PARALLEL PORT EXTENSION FDD.................................................................................................147
14.2 PARALLEL PORT EXTENSION 2FDD...............................................................................................147
14.3 FOUR FDD MODE ..................................................................................................................................148
15. ORDERING INFORMATION.........................................................................................148
16. HOW TO READ THE TOP MARKING .......................................................................148
17. PACKAGE DIMENSIONS...............................................................................................149
- VI -
Publication Release Date: March 1998
Revision 0.62
W83977TF
WINBOND I/O
GENERAL DESCRIPTION
The W83977TF is an evolving product from Winbond's most popular I/O chip W83877F --- which
integrates the disk drive adapter, serial port (UART), IrDA 1.0 SIR, parallel port, configurable plug-andplay registers for the whole chip --- plus additional powerful features: ACPI, 8042 keyboard controller
with PS/2 mouse support, 23 general purpose I/O ports, full 16-bit address decoding, OnNow keyboard
wake-up, OnNow mouse wake-up.
The disk drive adapter functions of W83977TF include a floppy disk drive controller compatible with the
industry standard 82077/ 765, data separator, write pre-compensation circuit, decode logic, data rate
selection, clock generator, drive interface control logic, and interrupt and DMA logic. The wide range of
functions integrated into the W83977TF greatly reduces the number of components required for
interfacing with floppy disk drives. The W83977TF supports four 360K, 720K, 1.2M, 1.44M, or 2.88M
disk drives and data transfer rates of 250 Kb/s, 300 Kb/s, 500 Kb/s,1 Mb/s, and 2 Mb/s.
The W83977TF provides two high-speed serial communication ports (UARTs), one of which supports
serial Infrared communication. Each UART includes a 16-byte send/receive FIFO, a programmable
baud rate generator, complete modem control capability, and a processor interrupt system. Both
UARTs provide legacy speed with baud rate up to 115.2k bps and also advanced speed with baud rates
of 230k, 460k, or 921k bps which support higher speed modems.
The W83977TF supports one PC-compatible printer port (SPP), Bi-directional Printer port (BPP) and
also Enhanced Parallel Port (EPP) and Extended Capabilities Port (ECP). Through the printer port
interface pins, also available are: Extension FDD Mode and Extension 2FDD Mode allowing one or two
external floppy disk drives to be connected.
The configuration registers support mode selection, function enable/disable, and power down function
selection. Furthermore, the configurable PnP features are compatible with the plug-and-play feature
TM
demand of Windows 95 , which makes system resource allocation more efficient than ever.
W83977TF provides functions that comply with ACPI (Advanced Configuration and Power Interface),
which includes support of legacy and ACPI power management through SMI or SCI function pins.
W83977TF also has auto power management to reduce power consumption.
The keyboard controller is based on 8042 compatible instruction set with a 2K Byte programmable
ROM
TM
-2, Phoenix
and a 256-Byte
RAM
bank.
Keyboard
BIOS
firmware
is
available
with
optional
AMIKEY
TM
MultiKey/42 , or customer code.
The W83977TF provides a set of flexible I/O control functions to the system designer through a set of
General Purpose I/O ports. These GPIO ports may serve as simple I/O or may be individually
configured to provide a predefined alternate function.
W83977TF is made to fully comply with Microsoft PC97 Hardware Design Guide. IRQs, DMAs, and
I/O space resource are flexible to adjust to meet ISA PnP requirement. Moreover W83977TF is made to
meet the specification of PC97's requirement in the power management: ACPI and DPM (Device
Power Management).
Another benifit is that W83977TF has the same pin assignment as W83977AF, W83977F, W83977ATF.
This makes the design very flexible.
-1-
Publication Release Date: April 1998
Preliminary Revision 0.62
W83977TF
PRELIMINARY
FEATURES
General
• Plug & Play 1.0A compatible
• Support 13 IRQs, 4 DMA channels, full 16-bit address decoding
• Capable of ISA Bus IRQ Sharing
• Compliant with Microsoft PC97 Hardware Design Guide
• Support DPM (Device Power Management), ACPI
• Report ACPI status interrupt by SCI signal issued from any of the 13 IQRs pins or GPIO xx
• Programmable configuration settings
• Single 24/48 Mhz clock input
FDC
• Compatible with IBM PC AT disk drive systems
• Variable write pre-compensation with track selectable capability
• Support vertical recording format
• DMA enable logic
• 16-byte data FIFOs
• Support floppy disk drives and tape drives
• Detects all overrun and underrun conditions
• Built-in address mark detection circuit to simplify the read electronics
• FDD anti-virus functions with software write protect and FDD write enable signal (write data signal was
forced to be inactive)
• Support up to four 3.5-inch or 5.25-inch floppy disk drives
• Completely compatible with industry standard 82077
• 360K/720K/1.2M/1.44M/2.88M format; 250K, 300K, 500K, 1M, 2M bps data transfer rate
• Support 3-mode FDD, and its Win95 driver
UART
• Two high-speed 16550 compatible UARTs with 16-byte send/receive FIFOs
• MIDI compatible
• Fully programmable serial-interface characteristics:
--- 5, 6, 7 or 8-bit characters
--- Even, odd or no parity bit generation/detection
--- 1, 1.5 or 2 stop bits generation
• Internal diagnostic capabilities:
--- Loop-back controls for communications link fault isolation
--- Break, parity, overrun, framing error simulation
• Programmable baud generator allows division of 1.8461 Mhz and 24 Mhz by 1 to (216-1)
Maximum baud rate up to 921k bps for 14.769 Mhz and 1.5M bps for 24 Mhz
-2-
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
Infrared
• Support IrDA version 1.0 SIR protocol with maximum baud rate up to 115.2K bps
• Support SHARP ASK-IR protocol with maximum baud rate up to 57,600 bps
• Support S/W driver for Windows95TM and Windows98TM (MemphisTM)
Parallel Port
• Compatible with IBM parallel port
• Support PS/2 compatible bi-directional parallel port
• Support Enhanced Parallel Port (EPP) − Compatible with IEEE 1284 specification
• Support Extended Capabilities Port (ECP) − Compatible with IEEE 1284 specification
• Extension FDD mode supports disk drive B; and Extension 2FDD mode supports disk drives A and B
through parallel port
• Enhanced printer port back-drive current protection
Keyboard Controller
TM
TM
• 8042 based with optional F/W from AMIKKEY -2, Phoenix MultiKey/42
with 2K bytes of programmable ROM, and 256 bytes of RAM
or customer code
• Asynchronous Access to Two Data Registers and One status Register
• Software compatibility with the 8042 and PC87911 microcontrollers
• Support PS/2 mouse
• Support port 92
• Support both interrupt and polling modes
• Fast Gate A20 and Hardware Keyboard Reset
• 8 Bit Timer/ Counter
• Support binary and BCD arithmetic
• 6MHz, 8 MHz, 12 MHz, or 16 MHz operating frequency
General Purpose I/O Ports
• 23 programmable general purpose I/O ports; 3 dedicate, 20 optional
• General purpose I/O ports can serve as simple I/O ports, interrupt steering inputs, watching dog timer
output, power LED output, infrared I/O pins, general purpose address decoder, KBC control I/O pins
OnNow Funtions
• Keyboard wake-up by programmable keys
• Mouse wake-up by programmable buttons
Package
• 128-pin PQFP
-3 -
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
PIN CONFIGURATION
I I
RR
QQ
1 1
2 1
I
RI I I I
QR R R R
1 QQQ Q
01 3 4 5
/
/ P
P A
A N
N S
S W
WO
I U
N, T,
I I I I
GG
R R R RA V A A A A V A
P PV
Q Q Q Q1 S 1 1 1 1 C 1 A A A A A A A A A A 2 2 S
6 7 8 95 S 4 3 2 1 C0 9 8 7 6 5 4 3 2 1 0 3 2 B
/
S
M
I,
G GMK
P PCC
2 2 L L
1 0 KK
/
R
I
B
/
R
I
A
1 1 1 9 9 9 9 9 9 9 9 9 9 8 8 8 8 8 8 8 8 8 8 7 7 7 7 7 7 7 7 7 7 6 6 6 6 6
0 0 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5
2 1 0
IRQ14/GP14
IRQ15/GP15
IOR
IOW
AEN
IOCHRDY
D0
D1
D2
D3
D4
D5
VCC
D6
D7
MR
DACK0/GP16
VSS
SCI/DRQ0/GP17
DACK1
DRQ1
DACK2
DRQ2
DACK3
DRQ3
TC
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
40
39
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
VBAT
XTAL1
VSS
XTAL2
MDATA
KDATA
KBLOCK/GP13
KBRST/GP12
GA20/GP11
VCC
DCDB
SOUTB/PEN48
SINB
DTRB
RTSB
DSRB
CTSB
DCDA
SOUTA/PENKBC
SINA
DTRA/PNPCSV
RTSA/HEFRAS
DSRA
CTSA
GP24
GP25
1 1 1 1 1 1 1 1 1 1 2 2 2 2 2 2 2 2 2 2 3 33 3 3 33 3 3
1 2 3 4 5 67 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 12 3 4 56 7 8
C
L
K
I
N
D
R
V
D
E
N
0
D/ / / / / / / /
R D H R W T WW S
VS E DP R E D T
DK A A A
E
ECDT K
P
NH A 0
1, G
G
P
1
0,
/
S
C
I
/
D
I
R
/ / /
MDD
OSS
B AB
/ / S P V B / PP V P P P PP P / / / /
M I L E C U A DD S D D D DD DS I E A
O NC C S C 7 6 S 5 4 3 2 1 0 L N RF
I I RD
A DT
Y K
E
NT
X
-4-
/
S
T
B
I
R
R
X
I
R
T
X
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
1. PIN DESCRIPTION
Note: Please refer to Section 11.2 DC CHARACTERISTICS for details.
I/O6t - TTL level bi-directional pin with 6 mA source-sink capability
I/O8t - TTL level bi-directional pin with 8 mA source-sink capability
I/O8 - CMOS level bi-directional pin with 8 mA source-sink capability
I/O12t - TTL level bi-directional pin with 12 mA source-sink capability
I/O12 - CMOS level bi-directional pin with 12 mA source-sink capability
I/O16u - CMOS level bi-directional pin with 16 mA source-sink capability with internal pull-up resistor
I/OD16u - CMOS level bi-directional pin open drain output with 16 mA sink capability with internal pull-up resistor
I/O24t - TTL level bi-directional pin with 24 mA source-sink capability
OUT8t - TTL level output pin with 8 mA source-sink capability
OUT12t
- TTL level output pin with 12 mA source-sink capability
OD12 - Open-drain output pin with 12 mA sink capability
OD24 - Open-drain output pin with 24 mA sink capability
INt - TTL level input pin
INc - CMOS level input pin
INcu - CMOS level input pin with internal pull-up resitor
INcs - CMOS level Schmitt-triggered input pin
INts - TTL level Schmitt-triggered input pin
INtsu - TTL level Schmitt-triggered input pin with internal pull-up resistor
1.1 Host Interface
SYMBOL
PIN
I/O
A0−A10
74-84
INt
System address bus bits 0-10
A11-A14
86-89
INt
System address bus bits 11-14
91
INt
System address bus bit 15
D0−D5
109114
I/O12t
System data bus bits 0-5
D6−D7
116117
I/O12t
System data bus bits 6-7
IOR
105
INts
CPU I/O read signal
IOW
106
INts
CPU I/O write signal
AEN
107
INts
System address bus enable
IOCHRDY
108
OD24
In EPP Mode, this pin is the IO Channel Ready output to extend
the host read/write cycle.
MR
118
INts
Master Reset; Active high; MR is low during normal operations.
A15
FUNCTION
-5 -
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Revision 0.62
W83977TF
PRELIMINARY
1.1 Host Interface, continued
SYMBOL
PIN
I/O
FUNCTION
119
INtsu
DMA Channel 0 Acknowledge signal. (CR2C bit 5_4 = 00, default)
GP16
(WDTO)
I/O12t
General purpose I/O port 1bit 6. (CR2C bit 5_4 = 01)
P15
I/O12t
DACK0
DRQ0
Alternate function from GP16: Watch dog timer output
121
OUT12t
GP17
(PLEDO)
I/O12t
P14
I/O12t
SCI
OUT12t
KBC P15 I/O port. (CR2C bit 5_4 = 10)
DMA Channel 0 request signal. (CR2C bit 7_6 = 00, default)
General purpose I/O port 1bit 7. (CR2C bit 7_6 = 01)
Alternate Function from GP17: Power LED output.
KBC P14 I/O port (CR2C bit 7_6 = 10)
System Control Interrupt (CR2C bit 7_6 = 11)
DACK1
122
INts
DMA Channel 1 Acknowledge signal
DRQ1
123
OUT12t
DACK2
124
INts
DRQ2
125
OUT12t
DACK3
126
INts
DRQ3
127
OUT12t
TC
128
INts
IRQ1
99
OUT12t
Interrupt request 1
IRQ3
98
OUT12t
Interrupt request 3
IRQ4
97
OUT12t
Interrupt request 4
IRQ5
96
OUT12t
Interrupt request 5
IRQ6
95
OUT12t
Interrupt request 6
IRQ7
94
OUT12t
Interrupt request 7
IRQ8
93
OUT12t
Interrupt request 8
IRQ9
92
OUT12t
Interrupt request 9
IRQ10
100
OUT12t
Interrupt request 10
IRQ11
101
OUT12t
Interrupt request 11
IRQ12
102
OUT12t
Interrupt request 12
DMA Channel 1 request signal
DMA Channel 2 Acknowledge signal
DMA Channel 2 request signal
DMA Channel 3 Acknowledge signal
DMA Channel 3 request signal
Terminal Count. When active, this pin indicates termination of a
DMA transfer.
-6-
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
1.1 Host Interface, continued
SYMBOL
IRQ14
PIN
I/O
103
OUT12t
GP14
I/O12t
FUNCTION
Interrupt request 14. (CR2C bit 1_0 = 00, default)
General purpose I/O port 1 bit 4. (CR2C bit 1_0 = 01)
( GPACS )
Alternate Function 1 from GP14: General purpose address
decode output.
(P17)
Alternate Function 2 from GP14: KBC P17 I/O port.
PLEDO
IRQ15
104
OUT12t
Power LED output. (CR2C bit 1_0 = 10)
OUT12t
Interrupt request 15.(CR2C bit 3_2 = 00, default)
I/O12t
GP15
( GPAWE )
Alternate Function 1 from GP15: General purpose address write
enable output.
(P12)
Alternate Function 2 from GP15: KBC P12 I/O port.
WDT
CLKIN
General purpose I/O port 1 bit 5. (CR2C bit 3_2 = 01)
OUT12t
1
INt
Watch-Dog timer output. (CR2C bit 3_2 = 10)
24 or 48 MHz clock input, selectable through bit 5 of CR24.
1.2 General Purpose I/O Port
SYMBOL
PIN
I/O
GP20
(KBRST)
69
I/O12t
SMI
70
OUT12t
GP21
I/O12t
(P13)
General purpose I/O port 2 bit 0.
Alternate Function from GP20: Keyboard reset (KBC P20)
For the power management, the SMI is active low by the power
management events, that generate and SCI in ACPI mode.
(CR2B bit 4_3 = 00, default)
General purpose I/O port 2 bit 1. (CR2B bit 4_3 = 01)
Alternate Function from GP21: KBC P13 I/O port.
P16
I/O12t
PANSWOUT
GP22
(P14)
72
OUT12t
I/O12t
PANSWIN
GP23
(P15)
73
IN12t
I/O12t
GP24
(P16)
40
KBC P16 I/O port. (CR2B bit 4_3 = 10)
Panel Switch output. (CR2B bit 5 = 0, default)
General purpose I/O port 2 bit 2. (CR2B bit 5 = 1)
Alternate Function from GP22: KBC P14 I/O port.
Panel Switch input. (CR2B bit 7_6 = 00, default)
General purpose I/O port 2 bit 3. (CR2B bit 7_6 = 01)
Alternate Function from GP23: KBC P15 I/O port
P13
GP25
(GA20)
FUNCTION
39
I/O12t
General purpose I/O port 2 bit 4 (CR2A bit 5_4 = 01)
Alternate Function from GP24: KBC P16 I/O port
I/O12t
KBC P13 I/O port. (CR2A bit 5_4 = 10)
I/O12
General purpose I/O port 2 bit 5.
Alternate Function from GP25: GATE A20 (KBC P21)
-7 -
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
1.3 Serial Port Interface
SYMBOL
PIN
I/O
CTSA
41
INt
CTSB
48
DSRA
42
DSRB
49
RTSA
43
DTRA
Clear To Send is the modem control input.
The function of these pins can be tested by reading Bit 4 of the
handshake status register.
INt
Data Set Ready. An active low signal indicates the modem or data
set is ready to establish a communication link and transfer data to
the UART.
I/O8t
UART A Request To Send. An active low signal informs the
modem or data set that the controller is ready to send data.
During power-on reset, this pin is pulled down internally and is
defined as HEFRAS, which provides the power-on value for CR26
bit 6 (HEFRAS). A 4.7 kΩ is recommended if intends to pull up.
(select 370H as configuration I/O port′s address)
HEFRAS
RTSB
FUNCTION
50
I/O8t
UART B Request To Send. An active low signal informs the
modem or data set that the controller is ready to send data.
44
I/O8t
UART A Data Terminal Ready. An active low signal informs the
modem or data set that the controller is ready to communicate.
During power-on reset, this pin is pulled down internally and is
defined as PNPCSV , which provides the power-on value for CR24
PNPCSV
bit 0 (PNPCSV ). A 4.7 kΩ is recommended if intends to pull up.
(clear the default value of FDC, UARTs, and PRT)
DTRB
SINA
SINB
SOUTA
51
I/O8t
45, 52
INt
46
I/O8t
53
I/O8t
47
INt
PEN48
DCDA
DCDB
Serial Input. Used to receive serial data through the
communication link.
UART A Serial Output. Used to transmit serial data out to the
communication link.
During power-on reset, this pin is pulled down internally and is
defined as PENKBC, which provides the power-on value for CR24
bit 2 (ENKBC). A 4.7 kΩ resistor is recommended if intends to pull
up. (enable KBC)
PENKBC
SOUTB
UART B Data Terminal Ready. An active low signal informs the
modem or data set that controller is ready to communicate.
54
UART B Serial Output. During power-on reset, this pin is pulled
down internally and is defined as PEN48, which provides the
power-on value for CR24 bit 6 (EN48). A 4.7 kΩ resistor is
recommended if intends to pull up.
Data Carrier Detect. An active low signal indicates the modem or
data set has detected a data carrier.
-8-
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
1.3 Serial Port Interface, continued
SYMBOL
PIN
I/O
RIA
65
INt
RIB
66
FUNCTION
Ring Indicator. An active low signal indicates that a ring signal is
being received from the modem or data set.
1.4 Infrared Interface
SYMBOL
IRRX
IRTX
PIN
I/O
37
38
INcs
OUT12t
FUNCTION
Infrared Receiver input.
Infrared Transmitter Output.
1.5 Multi-Mode Parallel Port
The following pins have alternate functions, which are controlled by CR28 and L3-CRF0.
SYMBOL
SLCT
PIN
I/O
18
INt
FUNCTION
PRINTER MODE: SLCT
An active high input on this pin indicates that the printer is selected.
This pin is pulled high internally. Refer to description of the
parallel port for definition of this pin in ECP and EPP mode.
OD12
EXTENSION FDD MODE: WE2
This pin is for Extension FDD B; its function is the same as the WE
pin of FDC.
OD12
EXTENSION 2FDD MODE: WE2
This pin is for Extension FDD A and B; it function is the same as
the WE pin of FDC.
PE
19
INt
PRINTER MODE: PE
An active high input on this pin indicates that the printer has
detected the end of the paper. This pin is pulled high internally.
Refer to description of the parallel port for definition of this pin in
ECP and EPP mode.
OD12
EXTENSION FDD MODE: WD2
This pin is for Extension FDD B; its function is the same as the
WD pin of FDC.
OD12
EXTENSION 2FDD MODE: WD2
This pin is for Extension FDD A and B; its function is the same as
the WD pin of FDC.
-9 -
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
1.5 Multi-Mode Parallel Port, continued
SYMBOL
BUSY
PIN
I/O
21
INt
FUNCTION
PRINTER MODE: BUSY
An active high input indicates that the printer is not ready to receive
data. This pin is pulled high internally. Refer to description of the
parallel port for definition of this pin in ECP and EPP mode.
OD12
EXTENSION FDD MODE: MOB2
This pin is for Extension FDD B; the function of this pin is the same
as the MOB pin of FDC.
OD12
EXTENSION 2FDD MODE: MOB2
This pin is for Extension FDD A and B; the function of this pin is the
same as the MOB pin of FDC.
ACK
22
INt
PRINTER MODE: ACK
An active low input on this pin indicates that the printer has
received data and is ready to accept more data. This pin is pulled
high internally. Refer to description of the parallel port for
definition of this pin in ECP and EPP mode.
OD12
EXTENSION FDD MODE: DSB2
This pin is for the Extension FDD B; its functions is the same as the
DSB pin of FDC.
OD12
EXTENSION 2FDD MODE: DSB2
This pin is for Extension FDD A and B; it functions is the same as
the DSB pin of FDC.
ERR
34
INt
PRINTER MODE: ERR
An active low input on this pin indicates that the printer has
encountered an error condition. This pin is pulled high internally.
Refer to description of the parallel port for definition of this pin in
ECP and EPP mode.
OD12
OD12
EXTENSION FDD MODE: HEAD2
This pin is for Extension FDD B; its function is the same as the
HEADpin of FDC.
EXTENSION 2FDD MODE: HEAD2
This pin is for Extension FDD A and B; its function is the same as
the HEAD pin of FDC.
-10-
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
1.5 Multi-Mode Parallel Port, continued
SYMBOL
SLIN
PIN
I/O
32
OD12
FUNCTION
PRINTER MODE: SLIN
Output line for detection of printer selection. This pin is pulled high
internally. Refer to description of the parallel port for definition of
this pin in ECP and EPP mode.
OD12
EXTENSION FDD MODE: STEP2
This pin is for Extension FDD B; its function is the same as the
STEP pin of FDC.
OD12
EXTENSION 2FDD MODE: STEP2
This pin is for Extension FDD A and B; its function is the same as
the STEP pin of FDC.
INIT
33
OD12
PRINTER MODE: INIT
Output line for the printer initialization. This pin is pulled high
internally. Refer to description of the parallel port for definition of
this pin in ECP and EPP mode.
OD12
EXTENSION FDD MODE: DIR2
This pin is for Extension FDD B; its function is the same as the DIR
pin of FDC.
OD12
AFD
35
OD12
EXTENSION 2FDD MODE: DIR2
This pin is for Extension FDD A and B; its function is the same as
the DIR pin of FDC.
PRINTER MODE: AFD
An active low output from this pin causes the printer to auto feed a
line after a line is printed. This pin is pulled high internally. Refer
to description of the parallel port for definition of this pin in ECP and
EPP mode.
OD12
EXTENSION FDD MODE: DRVDEN0
This pin is for Extension FDD B; its function is the same as the
DRVDEN0 pin of FDC.
OD12
EXTENSION 2FDD MODE: DRVDEN0
This pin is for Extension FDD A and B; its function is the same as
the DRVDEN0 pin of FDC.
-11 -
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
1.5 Multi-Mode Parallel Port, continued
SYMBOL
STB
PIN
I/O
36
OD12
FUNCTION
PRINTER MODE: STB
An active low output is used to latch the parallel data into the
printer. This pin is pulled high internally. Refer to description of the
parallel port for definition of this pin in ECP and EPP mode.
PD0
31
-
EXTENSION FDD MODE: This pin is a tri-state output.
-
EXTENSION 2FDD MODE: This pin is a tri-state output.
I/O24t
PRINTER MODE: PD0
Parallel port data bus bit 0. Refer to description of the parallel port
for definition of this pin in ECP and EPP mode.
INt
EXTENSION FDD MODE: INDEX2
This pin is for Extension FDD B; the function of this pin is the same
as the INDEX pin of FDC. It is pulled high internally.
INt
EXTENSION 2FDD MODE: INDEX2
This pin is for Extension FDD A and B; the function of this pin is the
same as the INDEX pin of FDC. It is pulled high internally.
PD1
30
I/O24t
PRINTER MODE: PD1
Parallel port data bus bit 1. Refer to description of the parallel port
for definition of this pin in ECP and EPP mode.
INt
EXTENSION FDD MODE: TRAK02
This pin is for Extension FDD B; the function of this pin is the same
as the TRAK 0 pin of FDC. It is pulled high internally.
INt
EXTENSION. 2FDD MODE: TRAK02
This pin is for Extension FDD A and B; the function of this pin is the
same as the TRAK 0 pin of FDC. It is pulled high internally.
PD2
29
I/O24t
PRINTER MODE: PD2
Parallel port data bus bit 2. Refer to description of the parallel port
for definition of this pin in ECP and EPP mode.
INt
EXTENSION FDD MODE: WP2
This pin is for Extension FDD B; the function of this pin is the same
as the WP pin of FDC. It is pulled high internally.
INt
EXTENSION. 2FDD MODE: WP2
This pin is for Extension FDD A and B; the function of this pin is the
same as the WP pin of FDC. It is pulled high internally.
-12-
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
1.5 Multi-Mode Parallel Port, continued
SYMBOL
PD3
PD4
PD5
PIN
I/O
FUNCTION
28
I/O24t
PRINTER MODE: PD3
Parallel port data bus bit 3. Refer to description of the parallel port
for definition of this pin in ECP and EPP mode.
INt
EXTENSION FDD MODE: RDATA2
This pin is for Extension FDD B; the function of this pin is the same
as the RDATA pin of FDC. It is pulled high internally.
INt
EXTENSION 2FDD MODE: RDATA2
This pin is for Extension FDD A and B; this function of this pin is the
same as the RDATA pin of FDC. It is pulled high internally.
PRINTER MODE: PD4
Parallel port data bus bit 4. Refer to description of the parallel port
for definition of this pin in ECP and EPP mode.
27
26
I/O24t
INt
EXTENSION FDD MODE: DSKCHG2
This pin is for Extension FDD B; the function of this pin is the same
as the DSKCHG pin of FDC. It is pulled high internally.
INt
EXTENSION 2FDD MODE: DSKCHG2
This pin is for Extension FDD A and B; this function of this pin is the
same as the DSKCHG pin of FDC. It is pulled high internally.
PRINTER MODE: PD5
Parallel port data bus bit 5. Refer to description of the parallel port
for definition of this pin in ECP and EPP mode.
EXTENSION FDD MODE: This pin is a tri-state output.
EXTENSION 2FDD MODE: This pin is a tri-state output.
I/O24t
PD6
24
I/O24t
-
PRINTER MODE: PD6
Parallel port data bus bit 6. Refer to description of the parallel port
for definition of this pin in ECP and EPP mode.
EXTENSION FDD MODE: This pin is a tri-state output.
OD24
EXTENSION. 2FDD MODE: MOA2
This pin is for Extension FDD A; its function is the same as the
MOA pin of FDC.
-13 -
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
1.5 Multi-Mode Parallel Port, continued
SYMBOL
PD7
PIN
I/O
23
I/O24t
FUNCTION
PRINTER MODE: PD7
Parallel port data bus bit 7. Refer to description of the parallel port
for definition of this pin in ECP and EPP mode.
OD24
EXTENSION FDD MODE: This pin is a tri-state output.
EXTENSION 2FDD MODE: DSA2
This pin is for Extension FDD A; its function is the same as the
DSA pin of FDC.
1.6 FDC Interface
SYMBOL
PIN
I/O
DRVDEN0
2
OD24
Drive Density Select bit 0.
DRVDEN1
3
OD24
Drive Density Select bit 1. (CR2A bit 1_0 = 00, default)
IO24t
General purpose I/O port 1 bit 0. (CR2A bit 1_0 = 01)
GP10
(IRQIN1)
FUNCTION
Alternate Function from GP10: Interrupt channel input.
P12
IO24t
SCI
OUT12t
KBC P12 I/O port. (CR2A bit 1_0 = 10)
System Control Interrupt (CR2A bit 1_0 = 11)
HEAD
5
OD24
Head select. This open drain output determines which disk drive
head is active.
Logic 1 = side 0
Logic 0 = side 1
WE
9
OD24
Write enable. An open drain output.
WD
10
OD24
Write data. This logic low open drain writes pre-compensation
serial data to the selected FDD. An open drain output.
STEP
11
OD24
Step output pulses. This active low open drain output produces a
pulse to move the head to another track.
DIR
12
OD24
Direction of the head step motor. An open drain output.
Logic 1 = outward motion
Logic 0 = inward motion
MOB
13
OD24
Motor B On. When set to 0, this pin enables disk drive 1. This is
an open drain output.
DSA
14
OD24
Drive Select A. When set to 0, this pin enables disk drive A. This
is an open drain output.
DSB
15
OD24
Drive Select B. When set to 0, this pin enables disk drive B. This
is an open drain output.
-14-
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
1.6 FDC Interface, continued
SYMBOL
PIN
I/O
FUNCTION
MOA
16
OD24
Motor A On. When set to 0, this pin enables disk drive 0. This is
an open drain output.
DSKCHG
4
INcs
Diskette change. This signal is active low at power on and
whenever the diskette is removed. This input pin is pulled up
internally by a 1 KΩ resistor. The resistor can be disabled by bit 7
of L0-CRF0 (FIPURDWN).
RDATA
6
INcs
The read data input signal from the FDD. This input pin is pulled
up internally by a 1 KΩ resistor. The resistor can be disabled by
bit 7 of L0-CRF0 (FIPURDWN).
WP
7
INcs
Write protected. This active low Schmitt input from the disk drive
indicates that the diskette is write-protected. This input pin is
pulled up internally by a 1 KΩ resistor. The resistor can be
disabled by bit 7 of L0-CRF0 (FIPURDWN).
TRAK0
8
INcs
Track 0. This Schmitt-triggered input from the disk drive is active
low when the head is positioned over the outermost track.
This
input pin is pulled up internally by a 1 KΩ resistor. The resistor
can be disabled by bit 7 of L0-CRF0 (FIPURDWN).
INDEX
17
INcs
This Schmitt-triggered input from the disk drive is active low when
the head is positioned over the beginning of a track marked by an
index hole. This input pin is pulled up internally by a 1 KΩ resistor.
The resistor can be disabled by bit 7 of L0-CRF0 (FIPURDWN).
I/O
FUNCTION
1.7 KBC Interface
SYMBOL
PIN
KDATA
59
I/OD16u
Keyboard Data
MDATA
60
I/OD16u
PS2 Mouse Data
KCLK
67
I/OD16u
Keyboard Clock
MCLK
68
I/OD16u
PS2 Mouse Clock
GA20
56
I/O12t
KBC GATE A20 (P21) Output. (CR2A bit 6 = 0, default)
I/O12t
General purpose I/O port 1 bit 1. (CR2A bit 6 = 1)
GP11
(IRQIN2)
KBRST
GP12
(WDTO)
Alternate Function from GP11: Interrupt channel input.
57
I/O12t
W83C45 Keyboard Reset (P20) Output. (CR2A bit 7 = 0, default)
I/O12t
General purpose I/O port 1 bit 2. (CR2A bit 7 = 1)
Alternate Function 1 from GP12 : Watchdog timer output.
-15 -
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
1.7 KBC Interface, continued
SYMBOL
KBLOCK
PIN
I/O
58
INts
GP13
I/O16t
FUNCTION
W83C45 KINH (P17) Input. (CR2B bit 0 = 0, default)
General purpose I/O port 1 bit 3. (CR2B bit 0 = 1)
1.8 POWER PINS
SYMBOL
PIN
FUNCTION
VCC
20, 55, 85,
115
+5V power supply for the digital circuitry
VSB
71
+5V stand-by power supply for the digital circuitry
GND
25, 62, 90,
120
Ground
1.9 ACPI Interface
SYMBOL
PIN
I/O
FUNCTION
VBAT
64
NA
battery voltage input
XTAL1
63
INC
32.768Khz Clock Input
XTAL2
61
O8t
32.768Khz Clock Output
-16-
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
2. FDC FUNCTIONAL DESCRIPTION
2.1 W83977TF FDC
The floppy disk controller of the W83977TF integrates all of the logic required for floppy disk control.
The FDC implements a PC/AT or PS/2 solution. All programmable options default to compatible
values. The FIFO provides better system performance in multi-master systems. The digital data
separator supports up to 2 M bits/sec data rate.
The FDC includes the following blocks: AT interface, Precompensation, Data Rate Selection, Digital
Data Separator, FIFO, and FDC Core.
2.1.1 AT interface
The interface consists of the standard asynchronous signals: RD , WR , A0-A3, IRQ, DMA control, and
a data bus. The address lines select between the configuration registers, the FIFO and control/status
registers. This interface can be switched between PC/AT, Model 30, or PS/2 normal modes. The PS/2
register sets are a superset of the registers found in a PC/AT.
2.1.2 FIFO (Data)
The FIFO is 16 bytes in size and has programmable threshold values. All command parameter
information and disk data transfers go through the FIFO. Data transfers are governed by the RQM and
DIO bits in the Main Status Register.
The FIFO defaults to disabled mode after any form of reset. This maintains PC/AT hardware
compatibility. The default values can be changed through the CONFIGURE command. The advantage
of the FIFO is that it allows the system a larger DMA latency without causing disk errors. The following
tables give several examples of the delays with a FIFO. The data are based upon the following formula:
THRESHOLD # × (1/DATA/RATE) *8 - 1.5 µS = DELAY
FIFO THRESHOLD
MAXIMUM DELAY TO SERVICING AT 500K BPS
Data Rate
1 Byte
1 × 16 µS - 1.5 µS = 14.5 µS
2 Byte
2 × 16 µS - 1.5 µS = 30.5 µS
8 Byte
8 × 16 µS - 1.5 µS = 6.5 µS
15 Byte
15 × 16 µS - 1.5 µS = 238.5 µS
FIFO THRESHOLD
MAXIMUM DELAY TO SERVICING AT 1M BPS
Data Rate
1 Byte
1 × 8 µS - 1.5 µS = 6.5 µS
2 Byte
2 × 8 µS - 1.5 µS = 14.5 µS
8 Byte
8 × 8 µS - 1.5 µS = 62.5 µS
15 Byte
15 × 8 µS - 1.5 µS = 118.5 µS
-17 -
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
At the start of a command the FIFO is always disabled and command parameters must be sent based
upon the RQM and DIO bit settings in the main status register. When the FDC enters the command
execution phase, it clears the FIFO of any data to ensure that invalid data are not transferred.
An overrun and underrun will terminate the current command and the data transfer. Disk writes will
complete the current sector by generating a 00 pattern and valid CRC. Reads require the host to
remove the remaining data so that the result phase may be entered.
DMA transfers are enabled with the SPECIFY command and are initiated by the FDC by activating the
DRQ pin during a data transfer command. The FIFO is enabled directly by asserting DACK and
addresses need not be valid.
Note that if the DMA controller is programmed to function in verify mode a pseudo read is performed by
the FDC based only on DACK . This mode is only available when the FDC has been configured into byte
mode (FIFO disabled) and is programmed to do a read. With the FIFO enabled the above operation is
performed by using the new VERIFY command. No DMA operation is needed.
2.1.3 Data Separator
The function of the data separator is to lock onto the incoming serial read data. When a lock is achieved
the serial front end logic of the chip is provided with a clock which is synchronized to the read data. The
synchronized clock, called the Data Window, is used to internally sample the serial data portion of the
bit cell, and the alternate state samples the clock portion. Serial to parallel conversion logic separates
the read data into clock and data bytes.
The Digital Data Separator (DDS) has three parts: control logic, error adjustment, and speed tracking.
The DDS circuit cycles once every 12 clock cycles ideally. Any data pulse input will be synchronized and
then adjusted by immediate error adjustment. The control logic will generate RDD and RWD for every
pulse input. During any cycle where no data pulse is present, the DDS cycles are based on speed. A
digital integrator is used to keep track of the speed changes in the input data stream.
2.1.4 Write Precompensation
The write precompensation logic is used to minimize bit shifts in the RDDATA stream from the disk
drive. Shifting of bits is a known phenomenon in magnetic media and is dependent on the disk media
and the floppy drive.
The FDC monitors the bit stream that is being sent to the drive. The data patterns that require
precompensation are well known. Depending upon the pattern, the bit is shifted either early or late
relative to the surrounding bits.
2.1.5 Perpendicular Recording Mode
The FDC is also capable of interfacing directly to perpendicular recording floppy drives. Perpendicular
recording differs from the traditional longitudinal method in that the magnetic bits are oriented vertically.
This scheme packs more data bits into the same area.
FDCs with perpendicular recording drives can read standard 3.5" floppy disks and can read and write
perpendicular media. Some manufacturers offer drives that can read and write standard and
perpendicular media in a perpendicular media drive.
A single command puts the FDC into perpendicular mode. All other commands operate as they
normally do. The perpendicular mode requires a 1 Mbps data rate for the FDC. At this data rate the
FIFO eases the host interface bottleneck due to the speed of data transfer to or from the disk.
-18-
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
2.1.6 FDC Core
The W83977TF FDC is capable of performing twenty commands. Each command is initiated by a multibyte transfer from the microprocessor. The result can also be a multi-byte transfer back to the
microprocessor. Each command consists of three phases: command, execution, and result.
Command
The microprocessor issues all required information to the controller to perform a specific operation.
Execution
The controller performs the specified operation.
Result
After the operation is completed, status information and other housekeeping information is provided to
the microprocessor.
2.1.7 FDC Commands
Command Symbol Descriptions:
C:
Cylinder number 0 - 256
D:
Data Pattern
DIR:
Step Direction
DIR = 0, step out
DIR = 1, step in
DS0:
Disk Drive Select 0
DS1:
Disk Drive Select 1
DTL:
Data Length
EC:
Enable Count
EOT:
End of Track
EFIFO:
Enable FIFO
EIS:
Enable Implied Seek
EOT:
End of track
FIFOTHR: FIFO Threshold
GAP:
Gap length selection
GPL:
Gap Length
H:
Head number
HDS:
Head number select
HLT:
Head Load Time
HUT:
Head Unload Time
LOCK:
Lock EFIFO, FIFOTHR, PTRTRK bits prevent affected by software reset
MFM:
MFM or FM Mode
MT:
Multitrack
N:
The number of data bytes written in a sector
NCN:
New Cylinder Number
ND:
Non-DMA Mode
OW:
Overwritten
PCN:
Present Cylinder Number
POLL:
Polling Disable
PRETRK: Precompensation Start Track Number
-19 -
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
R:
RCN:
R/W:
SC:
SK:
SRT:
ST0:
ST1:
ST2:
ST3:
WG:
Record
Relative Cylinder Number
Read/Write
Sector/per cylinder
Skip deleted data address mark
Step Rate Time
Status Register 0
Status Register 1
Status Register 2
Status Register 3
Write gate alters timing of WE
(1) Read Data
PHASE
R/W
D7
D6
Command
W
MT MFM
W
0
0
D5
D4
D3
SK
0
0
0
0
0
D2
1
D1
1
0
REMARKS
Command codes
HDS DS1 DS0
W
---------------------- C ------------------------
W
---------------------- H ------------------------
W
---------------------- R ------------------------
W
---------------------- N ------------------------
W
-------------------- EOT -----------------------
W
-------------------- GPL -----------------------
W
-------------------- DTL -----------------------
Execution
Result
D0
Sector ID information prior
to command execution
Data transfer between the
FDD and system
R
R
-------------------- ST0 -----------------------
R
-------------------- ST2 -----------------------
R
---------------------- C ------------------------
R
---------------------- H ------------------------
R
---------------------- R ------------------------
R
---------------------- N ------------------------
-------------------- ST1 -----------------------
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Status information after
command execution
Sector ID information after
command execution
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
(2) Read Deleted Data
PHASE
R/W
D7
D6
Command
W
MT MFM
W
0
0
D5
D4
D3
SK
0
1
0
0
0
D2
1
D1
0
D0
0
Command codes
HDS DS1 DS0
W
---------------------- C ------------------------
W
---------------------- H ------------------------
W
---------------------- R ------------------------
W
---------------------- N ------------------------
W
-------------------- EOT -----------------------
W
-------------------- GPL -----------------------
W
-------------------- DTL -----------------------
Execution
Result
REMARKS
Sector ID information prior
to command execution
Data transfer between the
FDD and system
R
-------------------- ST0 -----------------------
R
-------------------- ST1 -----------------------
R
-------------------- ST2 -----------------------
R
---------------------- C ------------------------
R
---------------------- H ------------------------
R
---------------------- R ------------------------
R
---------------------- N ------------------------
-21 -
Status information after
command execution
Sector ID information after
command execution
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
(3) Read A Track
PHASE
R/W
D7
Command
W
0
W
0
D6
MFM
0
D5
D4
D3
0
0
0
0
0
0
D2
0
D1
1
D0
0
Command codes
HDS DS1 DS0
W
---------------------- C ------------------------
W
---------------------- H ------------------------
W
---------------------- R ------------------------
W
---------------------- N ------------------------
W
-------------------- EOT -----------------------
W
-------------------- GPL -----------------------
W
-------------------- DTL -----------------------
Execution
Result
REMARKS
Sector ID information prior to
command execution
Data transfer between the
FDD and system; FDD reads
contents of all cylinders from
index hole to EOT
R
-------------------- ST0 -----------------------
R
-------------------- ST1 -----------------------
R
-------------------- ST2 -----------------------
R
---------------------- C ------------------------
R
---------------------- H ------------------------
R
---------------------- R ------------------------
R
---------------------- N ------------------------
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Status information after
command execution
Sector ID information after
command execution
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
(4) Read ID
PHASE
R/W
D7
Command
W
0
W
0
D6
D5
D4
D3
MFM
0
0
1
0
0
0
0
D2
0
D1
1
D0
0
Command codes
HDS DS1 DS0
Execution
Result
REMARKS
The first correct ID
information on the cylinder
is stored in Data Register
R
-------------------- ST0 -----------------------
R
-------------------- ST1 -----------------------
R
-------------------- ST2 -----------------------
R
R
---------------------- C ------------------------
R
---------------------- R ------------------------
R
---------------------- N ------------------------
Status information after
command execution
Disk status after the
command has been
completed
---------------------- H ------------------------
(5) Verify
PHASE
Command
R/W
D7
D6
D5
D4
D3
W
MT MFM SK
1
0
W
EC
0
0
0
0
D2
1
D1
1
D0
0
REMARKS
Command codes
HDS DS1 DS0
W
---------------------- C ------------------------
W
---------------------- H ------------------------
W
---------------------- R ------------------------
W
---------------------- N ------------------------
W
-------------------- EOT -----------------------
W
-------------------- GPL -----------------------
Sector ID information prior
to command execution
-------------------- DTL/SC ------------------Execution
Result
No data transfer takes
place
R
-------------------- ST0 -----------------------
R
-------------------- ST1 -----------------------
R
-------------------- ST2 -----------------------
R
---------------------- C ------------------------
R
---------------------- H ------------------------
R
---------------------- R ------------------------
R
---------------------- N ------------------------
-23 -
Status information after
command execution
Sector ID information after
command execution
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
(6) Version
PHASE
R/W
D7
D6
D5
D4
D3
D2
D1
D0
REMARKS
Command
W
0
0
0
1
0
0
0
0
Command code
Result
R
1
0
0
1
0
0
0
0
Enhanced controller
PHASE
R/W
D7
D6
D5
D4
D3
Command
W
MT MFM
0
0
0
W
0
0
0
0
(7) Write Data
0
D2
1
D1
0
D0
1
Command codes
HDS DS1 DS0
W
---------------------- C ------------------------
W
---------------------- H ------------------------
W
---------------------- R ------------------------
W
---------------------- N ------------------------
W
-------------------- EOT -----------------------
W
-------------------- GPL -----------------------
W
-------------------- DTL -----------------------
Execution
Result
REMARKS
Sector ID information prior
to Command execution
Data transfer between the
FDD and system
R
-------------------- ST0 -----------------------
R
-------------------- ST1 -----------------------
R
-------------------- ST2 -----------------------
R
---------------------- C ------------------------
R
---------------------- H ------------------------
R
---------------------- R ------------------------
R
---------------------- N ------------------------
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Status information after
Command execution
Sector ID information after
Command execution
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
(8) Write Deleted Data
PHASE
R/W
Command
W
W
D7
D6
D5
D4
MT MFM
0
0
1
0
0
0
0
0
D3
D2
0
D1
0
D0
1
Command codes
HDS DS1 DS0
W
---------------------- C ------------------------
W
---------------------- H ------------------------
W
---------------------- R ------------------------
W
---------------------- N ------------------------
W
-------------------- EOT -----------------------
W
-------------------- GPL -----------------------
W
-------------------- DTL -----------------------
Execution
Result
REMARKS
Sector ID information prior
to command execution
Data transfer between the
FDD and system
R
-------------------- ST0 -----------------------
R
-------------------- ST1 -----------------------
R
-------------------- ST2 -----------------------
R
---------------------- C ------------------------
R
---------------------- H ------------------------
R
---------------------- R ------------------------
R
---------------------- N ------------------------
-25 -
Status information after
command execution
Sector ID information after
command execution
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
(9) Format A Track
PHASE
Command
Execution
for Each
Sector
Repeat:
R/W
D7
D6
D5
D4
D3
W
0
MFM
0
0
1
W
0
0
0
0
0
D2
D1
1
D0
0
1
REMARKS
Command codes
HDS DS1 DS0
W
---------------------- N ------------------------
Bytes/Sector
W
--------------------- SC -----------------------
Sectors/Cylinder
W
--------------------- GPL ---------------------
Gap 3
W
---------------------- D ------------------------
Filler Byte
W
---------------------- C ------------------------
Input Sector Parameters
W
---------------------- H ------------------------
W
---------------------- R ------------------------
W
---------------------- N ------------------------
R
-------------------- ST0 -----------------------
R
-------------------- ST1 -----------------------
R
-------------------- ST2 -----------------------
R
R
---------------- Undefined -------------------
R
---------------- Undefined -------------------
R
---------------- Undefined -------------------
Result
Status information after
command execution
---------------- Undefined -------------------
(10) Recalibrate
PHASE
R/W
D7
D6
D5
D4
D3
Command
W
0
0
0
0
0
W
0
0
0
0
0
D2
1
0
D1
1
D0
1
REMARKS
Command codes
DS1 DS0
Execution
Head retracted to Track 0
Interrupt
(11) Sense Interrupt Status
PHASE
R/W
D7
D6
D5
0
0
D4
Command
W
0
Result
R
---------------- ST0 -------------------------
R
---------------- PCN -------------------------
0
D3
1
D2
0
-26-
D1
0
D0
0
REMARKS
Command code
Status information at the end
of each seek operation
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
(12) Specify
PHASE
R/W
D7
W
0
W
| ---------SRT ----------- | --------- HUT ---------- |
W
|------------ HLT ----------------------------------| ND
Command
D6
0
D5
0
D4
0
D3
D2
0
0
D1
1
D0
1
REMARKS
Command codes
(13) Seek
PHASE
R/W
D7
D6
D5
D4
W
0
0
0
0
1
W
0
0
0
0
0
Command
W
Execution
D3
D2
1
D1
1
D0
1
REMARKS
Command codes
HDS DS1 DS0
-------------------- NCN -----------------------
R
Head positioned over proper
cylinder on diskette
(14) Configure
PHASE
Command
R/W
D7
D6
D5
D4
D3
W
0
0
0
1
0
0
1
1
W
0
0
0
0
0
0
0
0
W
W
0
D2
D1
D0
REMARKS
Configure information
EIS EFIFO POLL | ------ FIFOTHR ----|
| --------------------PRETRK ----------------------- |
Execution
Internal registers written
(15) Relative Seek
PHASE
Command
R/W
D7
D6
W
1
W
0
W
D5
D4
D3
DIR
0
0
1
0
0
0
0
D2
1
D1
1
D0
1
REMARKS
Command codes
HDS DS1 DS0
| -------------------- RCN ---------------------------- |
-27 -
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
(16) Dumpreg
PHASE
R/W
D7
D6
D5
D4
0
0
0
Command
W
0
Result
R
----------------------- PCN-Drive 0--------------------
R
----------------------- PCN-Drive 1 -------------------
R
----------------------- PCN-Drive 2--------------------
R
----------------------- PCN-Drive 3 -------------------
R
--------SRT ------------------ | --------- HUT --------
R
----------- HLT -----------------------------------| ND
R
------------------------ SC/EOT ---------------------D3
D2
D3
1
D2
1
D1
D1
1
D0
0
D0 GAP
REMARKS
Registers placed in FIFO
R
LOCK 0
WG
R
0 EIS EFIFO POLL | ------ FIFOTHR --------
R
-----------------------PRETRK -------------------------
(17) Perpendicular Mode
PHASE
Command
R/W
D7
D6
D5
D4
D3
W
0
0
0
1
0
W
OW
0
D3
D2
D1
R/W
D7
D6
D2
0
D1
1
D0
0
REMARKS
Command Code
D0 GAP WG
(18) Lock
PHASE
Command
W
Result
R
LOCK 0
0
0
D5
D4
D3
D2
D1
D0
0
1
0
1
0
0
0
LOCK
0
0
0
0
REMARKS
Command Code
(19) Sense Drive Status
PHASE
Command
Result
R/W
D7
D6
D5
D4
W
0
0
0
0
0
W
0
0
0
0
0
R
D3
D2
1
D1
0
D0
0
REMARKS
Command Code
HDS DS1 DS0
---------------- ST3 -------------------------
Status information about
disk drive
(20) Invalid
PHASE
R/W
D7
D6
D5
D4
D3
D2
D1
D0
REMARKS
Command
W
------------- Invalid Codes -----------------
Invalid codes (no operationFDC goes to standby state)
Result
R
-------------------- ST0 ----------------------
ST0 = 80H
-28-
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
2.2 Register Descriptions
There are several status, data, and control registers in W83977TF. These registers are defined below:
ADDRESS
REGISTER
OFFSET
base address + 0
base address + 1
base address + 2
base address + 3
base address + 4
base address + 5
base address + 7
READ
SA REGISTER
SB REGISTER
WRITE
DO REGISTER
TD REGISTER
DR REGISTER
DT (FIFO) REGISTER
CC REGISTER
TD REGISTER
MS REGISTER
DT (FIFO) REGISTER
DI REGISTER
2.2.1 Status Register A (SA Register) (Read base address + 0)
This register is used to monitor several disk interface pins in PS/2 and Model 30 modes. In PS/2 mode,
the bit definitions for this register are as follows:
7
6
5
4
2
3
1
0
DIR
WP
INDEX
HEAD
TRAK0
STEP
DRV2
INIT PENDING
INIT PENDING (Bit 7):
This bit indicates the value of the floppy disk interrupt output.
DRV 2 (Bit 6):
0
A second drive has been installed
1
A second drive has not been installed
STEP (Bit 5):
This bit indicates the complement of STEP output.
TRAK0 (Bit 4):
This bit indicates the value of TRAK0 input.
HEAD (Bit 3):
-29 -
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
This bit indicates the complement of HEAD output.
0
side 0
1
side 1
INDEX (Bit 2):
This bit indicates the value of INDEX output.
WP (Bit 1):
0disk is write-protected
1disk is not write-protected
DIR (Bit 0)
This bit indicates the direction of head movement.
0
outward direction
1
inward direction
In PS/2 Model 30 mode, the bit definitions for this register are as follows:
7
6
5
4
2
3
1
0
DIR
WP
INDEX
HEAD
TRAK0
STEP F/F
DRQ
INIT PENDING
INIT PENDING (Bit 7):
This bit indicates the value of the floppy disk interrupt output.
DRQ (Bit 6):
This bit indicates the value of DRQ output pin.
STEP F/F (Bit 5):
This bit indicates the complement of latched STEP output.
TRAK0 (Bit 4):
This bit indicates the complement of TRAK0 input.
HEAD (Bit 3):
This bit indicates the value of HEAD output.
0
side 1
1
side 0
-30-
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
INDEX (Bit 2):
This bit indicates the complement of INDEX output.
WP (Bit 1):
0
disk is not write-protected
1
disk is write-protected
DIR (Bit 0)
This bit indicates the direction of head movement.
0
inward direction
1
outward direction
2.2.2 Status Register B (SB Register) (Read base address + 1)
This register is used to monitor several disk interface pins in PS/2 and Model 30 modes. In PS/2 mode,
the bit definitions for this register are as follows:
7
6
1
1
5
4
3
2
1
0
MOT EN A
MOT EN B
WE
RDATA Toggle
WDATA Toggle
Drive SEL0
Drive SEL0 (Bit 5):
This bit indicates the status of DO REGISTER bit 0 (drive select bit 0).
WDATA Toggle (Bit 4):
This bit changes state at every rising edge of the WD output pin.
RDATA Toggle (Bit 3):
This bit changes state at every rising edge of the RDATA output pin.
WE (Bit 2):
This bit indicates the complement of the WE output pin.
MOT EN B (Bit 1)
This bit indicates the complement of the MOB output pin.
MOT EN A (Bit 0)
This bit indicates the complement of the MOA output pin.
In PS/2 Model 30 mode, the bit definitions for this register are as follows:
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Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
7
6
5
4
3
2
1
0
DSC
DSD
WE F/F
RDATA F/F
WD F/F
DSA
DSB
DRV2
DRV2 (Bit 7):
0
A second drive has been installed
1
A second drive has not been installed
DSB (Bit 6):
This bit indicates the status of DSB output pin.
DSA (Bit 5):
This bit indicates the status of DSA output pin.
WD F/F(Bit 4):
This bit indicates the complement of the latched WD output pin at every rising edge of the WD output
pin.
RDATA F/F(Bit 3):
This bit indicates the complement of the latched RDATA output pin .
WE F/F (Bit 2):
This bit indicates the complement of latched WE output pin.
DSD (Bit 1):
0
Drive D has been selected
1
Drive D has not been selected
DSC (Bit 0):
0
Drive C has been selected
1
Drive C has not been selected
-32-
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
2.2.3 Digital Output Register (DO Register) (Write base address + 2)
The Digital Output Register is a write-only register controlling drive motors, drive selection, DRQ/IRQ
enable, and FDC resetting. All the bits in this register are cleared by the MR pin. The bit definitions are
as follows:
7
6
5
3
4
1-0
2
Drive Select: 00 select drive A
01 select drive B
10 select drive C
11 select drive D
Floppy Disk Controller Reset
Active low resets FDC
DMA and INT Enable
Active high enable DRQ/IRQ
Motor Enable A. Motor A on when active high
Motor Enable B. Motor B on when active high
Motor Enable C. Motor C on when active high
Motor Enable D. Motor D on when active high
2.2.4 Tape Drive Register (TD Register) (Read base address + 3)
This register is used to assign a particular drive number to the tape drive support mode of the data
separator. This register also holds the media ID, drive type, and floppy boot drive information of the
floppy disk drive. In normal floppy mode, this register includes only bit 0 and 1. The bit definitions are as
follows:
7
6
5
4
3
2
X
X
X
X
X
X
1
0
Tape sel 0
Tape sel 1
If three mode FDD function is enabled (EN3MODE = 1 in Logical Device 0 CRF0 bit:0), the bit definitions
are as follows:
7
6
5
4
3
2
1
0
Tape Sel 0
Tape Sel 1
Floppy boot drive 0
Floppy boot drive 1
Drive type ID0
Drive type ID1
Media ID0
Media ID1
-33 -
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
Media ID1 Media ID0 (Bit 7, 6):
These two bits are read only. These two bits reflect the value of Logical Device 0 CRF1 bit 4,5.
Drive type ID1 Drive type ID0 (Bit 5, 4):
These two bits reflect two of the bits of Logical Device 0 CRF2. Which two bits are reflected depends on
the last drive selected in the DO REGISTER.
Floppy Boot drive 1, 0 (Bit 3, 2):
These two bits reflect the value of Logical Device 0 CRF1 bit 7,6.
Tape Sel 1, Tape Sel 0 (Bit 1, 0):
These two bits assign a logical drive number to the tape drive. Drive 0 is not available as a tape drive
and is reserved as the floppy disk boot drive.
TAPE SEL 1
0
0
1
1
TAPE SEL 0
0
1
0
1
DRIVE SELECTED
None
1
2
3
2.2.5 Main Status Register (MS Register) (Read base address + 4)
The Main Status Register is used to control the flow of data between the microprocessor and the
controller. The bit definitions for this register are as follows:
7
6
5
4
3
2
1
0
FDD 0 Busy, (D0B = 1), FDD number 0 is in the SEEK mode.
FDD 1 Busy, (D1B = 1), FDD number 1 is in the SEEK mode.
FDD 2 Busy, (D2B = 1), FDD number 2 is in the SEEK mode.
FDD 3 Busy, (D3B = 1), FDD number 3 is in the SEEK mode.
FDC Busy, (CB). A read or write command is in the process when CB = HIGH.
Non-DMA mode, the FDC is in the non-DMA mode, this bit is set only during the
execution phase in non-DMA mode.
Transition to LOW state indicates execution phase has ended.
DATA INPUT/OUTPUT, (DIO). If DIO= HIGH then transfer is from Data Register to the processor.
If DIO = LOW then transfer is from processor to Data Register.
Request for Master (RQM). A high on this bit indicates Data Register is ready to send or receive data to or from the processor.
2.2.6 Data Rate Register (DR Register) (Write base address + 4)
The Data Rate Register is used to set the transfer rate and write precompensation. The data rate of the
FDC is programmed by the CC REGISTER for PC-AT and PS/2 Model 30 and PS/2 mode, and not by
the DR REGISTER. The real data rate is determined by the most recent write to either of the DR
REGISTER or CC REGISTER.
-34-
Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
7
6
5
4
3
2
1
0
0
DRATE0
DRATE1
PRECOMP0
PRECOMP1
PRECOMP2
POWER DOWN
S/W RESET
S/W RESET (Bit 7):
This bit is the software reset bit.
POWER-DOWN (Bit 6):
0
FDC in normal mode
1
FDC in power-down mode
PRECOMP2 PRECOMP1 PRECOMP0 (Bit 4, 3, 2):
These three bits select the value of write precompensation. The following tables show the
precompensation values for the combination of these bits.
PRECOMP
2
1
0
PRECOMPENSATION DELAY
250K - 1 Mbps
2 Mbps Tape drive
0
0
0
Default Delays
Default Delays
0
0
1
41.67 nS
20.8 nS
0
1
0
83.34 nS
41.17 nS
0
1
1
125.00 nS
62.5nS
1
0
0
166.67 nS
83.3 nS
1
0
1
208.33 nS
104.2 nS
1
1
0
250.00 nS
125.00 nS
1
1
1
0.00 nS (disabled)
0.00 nS (disabled)
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Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
DATA RATE
250 KB/S
300 KB/S
500 KB/S
1 MB/S
2 MB/S
DEFAULT PRECOMPENSATION DELAYS
125 nS
125 nS
125 nS
41.67nS
20.8 nS
DRATE1 DRATE0 (Bit 1, 0):
These two bits select the data rate of the FDC and reduced write current control.
00 500 KB/S (MFM), 250 KB/S (FM), RWC = 1
01 300 KB/S (MFM), 150 KB/S (FM), RWC = 0
10 250 KB/S (MFM), 125 KB/S (FM), RWC = 0
11 1 MB/S (MFM), Illegal (FM), RWC = 1
The 2 MB/S data rate for Tape drive is only supported by setting 01 to DRATE1 and DRATE0 bits, as
well as setting 10 to DRT1 and DRT0 bits which are two of the Configure Register CRF4 or CRF5 bits in
logic device 0. Please refer to the function description of CRF4 or CRF5 and data rate table for
individual data rates setting.
2.2.7 FIFO Register (R/W base address + 5)
The Data Register consists of four status registers in a stack with only one register presented to the data
bus at a time. This register stores data, commands, and parameters and provides diskette-drive status
information. Data bytes are passed through the data register to program or obtain results after a
command. In the W83977TF, this register defaults to FIFO disabled mode after reset. The FIFO can
change its value and enable its operation through the CONFIGURE command.
Status Register 0 (ST0)
7-6
5
4
3
2
1-0
US1, US0 Drive Select:
00 Drive A selected
01 Drive B selected
10 Drive C selected
11 Drive D selected
HD Head address:
1 Head selected
0 Head selected
NR Not Ready:
1 Drive is not ready
0 Drive is ready
EC Equipment Check:
1 When a fault signal is received from the FDD or the track
0 signal fails to occur after 77 step pulses
0 No error
SE Seek end:
1 seek end
0 seek error
IC Interrupt Code:
00 Normal termination of command
01 Abnormal termination of command
10 Invalid command issue
11 Abnormal termination because the ready signal from FDD changed state during command execution
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Revision 0.62
W83977TF
PRELIMINARY
Status Register 1 (ST1)
7
6
5
4
3
2
1
0
Missing Address Mark. 1 When the FDC cannot detect the data address mark
or the data address mark has been deleted.
NW (Not Writable). 1 If a write Protect signal is detected from the diskette drive during
execution of write data.
ND (No DATA). 1 If specified sector cannot be found during execution of a read, write or verifly data.
Not used. This bit is always 0.
OR (Over Rum). 1 If the FDC is not serviced by the host system within a certain time interval during data transfer.
DE (data Error).1 When the FDC detects a CRC error in either the ID field or the data field.
Not used. This bit is always 0.
EN (End of track). 1 When the FDC tries to access a sector beyond the final sector of a cylinder.
Status Register 2 (ST2)
7
6
5
4
3
2
1
0
MD (Missing Address Mark in Data Field).
1 If the FDC cannot find a data address mark
(or the address mark has been deleted)
when reading data from the media
0 No error
BC (Bad Cylinder)
1 Bad Cylinder
0 No error
SN (Scan Not satisfied)
1 During execution of the Scan command
0 No error
SH (Scan Equal Hit)
1 During execution of the Scan command, if the equal condition is satisfied
0 No error
WC (Wrong Cylinder)
1 Indicates wrong Cylinder
DD (Data error in the Data field)
1 If the FDC detects a CRC error in the data field
0 No error
CM (Control Mark)
1 During execution of the read data or scan command
0 No error
Not used. This bit is always 0
Status Register 3 (ST3)
7
6
5
4
3
2
1
0
US0 Unit Select 0
US1 Unit Select 1
HD Head Address
TS Two-Side
TO Track 0
RY Ready
WP Write Protected
FT Fault
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Revision 0.62
W83977TF
PRELIMINARY
2.2.8 Digital Input Register (DI Register) (Read base address + 7)
The Digital Input Register is an 8-bit read-only register used for diagnostic purposes. In a PC/XT or AT
only Bit 7 is checked by the BIOS. When the register is read, Bit 7 shows the complement of DSKCHG ,
while other bits of the data bus remain in tri-state. Bit definitions are as follows:
7
6
5
4
3
x
x
x
x
2
1
0
x x x
for the hard disk controller
x Reserved
During a read of this register, these bits are in tri-state
DSKCHG
In the PS/2 mode, the bit definitions are as follows:
7
6
5
4
3
1
1
1
1
2
0
1
HIGH DENS
DRATE0
DRATE1
DSKCHG
DSKCHG (Bit 7):
This bit indicates the complement of the DSKCHG input.
Bit 6-3: These bits are always a logic 1 during a read.
DRATE1 DRATE0 (Bit 2, 1):
These two bits select the data rate of the FDC. Refer to the DR register bits 1 and 0 for the settings
corresponding to the individual data rates.
HIGH DENS (Bit 0):
0
500 KB/S or 1 MB/S data rate (high density FDD)
1
250 KB/S or 300 KB/S data rate
In the PS/2 Model 30 mode, the bit definitions are as follows:
7
6
5
4
0
0
0
3
2
1
0
DRATE0
DRATE1
NOPREC
DMAEN
DSKCHG
DSKCHG (Bit 7):
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Revision 0.62
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PRELIMINARY
This bit indicates the status of DSKCHG input.
Bit 6-4: These bits are always a logic 1 during a read.
DMAEN (Bit 3):
This bit indicates the value of DO REGISTER bit 3.
NOPREC (Bit 2):
This bit indicates the value of CC REGISTER NOPREC bit.
DRATE1 DRATE0 (Bit 1, 0):
These two bits select the data rate of the FDC.
2.2.9 Configuration Control Register (CC Register) (Write base address + 7)
This register is used to control the data rate. In the PC/AT and PS/2 mode, the bit definitions are as
follows:
7
6
5
4
3
2
x
x
x
x
x
x
1
0
DRATE0
DRATE1
X: Reserved
Bit 7-2: Reserved. These bits should be set to 0.
DRATE1 DRATE0 (Bit 1, 0):
These two bits select the data rate of the FDC.
In the PS/2 Model 30 mode, the bit definitions are as follows:
7
6
5
4
3
X
X
X
X
X
2
1
0
DRATE0
DRATE1
NOPREC
X: Reserved
Bit 7-3: Reserved. These bits should be set to 0.
NOPREC (Bit 2):
This bit indicates no precompensation. It has no function and can be set by software.
DRATE1 DRATE0 (Bit 1, 0):
These two bits select the data rate of the FDC.
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Publication Release Date: April 1998
Revision 0.62
W83977TF
PRELIMINARY
3. UART PORT
3.1 Universal Asynchronous Receiver/Transmitter (UART A, UART B)
The UARTs are used to convert parallel data into serial format on the transmit side and convert serial
data to parallel format on the receiver side. The serial format, in order of transmission and reception, is
a start bit, followed by five to eight data bits, a parity bit (if programmed) and one, one and half (five-bit
format only) or two stop bits. The UARTs are capable of handling divisors of 1 to 65535 and producing
a 16x clock for driving the internal transmitter logic. Provisions are also included to use this 16x clock to
drive the receiver logic. The UARTs also support the MIDI data rate. Furthermore, the UARTs also
include complete modem control capability and a processor interrupt system that may be software
trailed to the computing time required to handle the communication link. The UARTs have a FIFO
mode to reduce the number of interrupts presented to the CPU. In each UART, there are 16-byte FIFOs
for both receive and transmit mode.
3.2 Register Address
3.2.1 UART Control Register (UCR) (Read/Write)
The UART Control Register controls and defines the protocol for asynchronous data communications,
including data length, stop bit, parity, and baud rate selection.
7
6
5
4
3
2
1
0
Data length select bit 0 (DLS0)
Data length select bit 1(DLS1)
Multiple stop bits enable (MSBE)
Parity bit enable (PBE)
Even parity enable (EPE)
Parity bit fixed enable (PBFE)
Set silence enable (SSE)
Baudrate divisor latch access bit (BDLAB)
Bit 7: BDLAB. When this bit is set to a logical 1, designers can access the divisor (in 16-bit binary format)
from the divisor latches of the baudrate generator during a read or write operation. When this bit
is reset, the Receiver Buffer Register, the Transmitter Buffer Register, or the Interrupt Control
Register can be accessed.
Bit 6: SSE. A logical 1 forces the Serial Output (SOUT) to a silent state (a logical 0). Only IRTX is
affected by this bit; the transmitter is not affected.
Bit 5: PBFE. When PBE and PBFE of UCR are both set to a logical 1,
(1) if EPE is logical 1, the parity bit is fixed as logical 0 to transmit and check.
(2) if EPE is logical 0, the parity bit is fixed as logical 1 to transmit and check.
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Revision 0.62
W83977TF
PRELIMINARY
TABLE 3-1 UART Register Bit Map
Bit Number
Register Address Base
+0
BDLAB = 0
Receiver
Buffer
Register
(Read Only)
+0
Transmitter
BDLAB = 0 Buffer Register
(Write Only)
+1
BDLAB = 0
Interrupt
Control
Register
RBR
TBR
ICR
0
1
2
3
4
5
6
7
RX Data
RX Data
RX Data
RX Data
RX Data
RX Data
RX Data
RX Data
Bit 0
Bit 1
Bit 2
Bit 3
Bit 4
Bit 5
Bit 6
Bit 7
TX Data
TX Data
TX Data
TX Data
TX Data
TX Data
TX Data
TX Data
Bit 0
Bit 1
Bit 2
Bit 3
Bit 4
Bit 5
Bit 6
Bit 7
RBR Data
Ready
Interrupt
Enable
(ERDRI)
TBR
Empty
Interrupt
Enable
(ETBREI)
USR
Interrupt
Enable
HSR
Interrupt
Enable
0
0
0
0
(EUSRI)
(EHSRI)
"0" if Interrupt
Pending
Interrupt
Status
Interrupt
Status
Interrupt
Status
0
0
Bit (0)
Bit (1)
Bit (2)**
FIFOs
FIFOs
Enabled
Enabled
Interrupt Status
Register
(Read Only)
ISR
**
**
+2
UART FIFO
Control
Register
(Write Only)
UFR
FIFO
Enable
RCVR
FIFO
Reset
XMIT
FIFO
Reset
DMA
Mode
Select
Reserved
Reversed
RX
Interrupt
Active Level
(LSB)
RX
Interrupt
Active Level
(MSB)
+3
UART Control
Register
UCR
Data
Length
Select
Bit 0
(DLS0)
Data
Length
Select
Bit 1
(DLS1)
Multiple
Stop Bits
Enable
Parity
Bit
Enable
Even
Parity
Enable
Parity
Bit Fixed
Enable
Set
Silence
Enable
(MSBE)
(PBE)
(EPE)
PBFE)
(SSE)
Baudrate
Divisor
Latch
Access Bit
(BDLAB)
+2
+4
Handshake
Control
Register
HCR
Data
Terminal
Ready
(DTR)
Request
to
Send
(RTS)
Loopback
RI
Input
IRQ
Enable
Internal
Loopback
Enable
0
0
0
+5
UART Status
Register
USR
RBR Data
Ready
Overrun
Error
Parity Bit
Error
TSR
Empty
(OER)
(PBER)
Silent
Byte
Detected
(SBD)
TBR
Empty
(RDR)
No Stop
Bit
Error
(NSER)
(TBRE)
(TSRE)
RX FIFO
Error
Indication
(RFEI) **
CTS
Toggling
DSR
Toggling
RI Falling
Edge
DCD
Toggling
Clear
to Send
Data Set
Ready
Ring
Indicator
+6
Handshake
Status Register
HSR
(TCTS)
(TDSR)
(FERI)
(TDCD)
(CTS)
(DSR)
(RI)
Data Carrier
Detect
(DCD)
+7
User Defined
Register
UDR
Bit 0
Bit 1
Bit 2
Bit 3
Bit 4
Bit 5
Bit 6
Bit 7
+0
Baudrate
Divisor Latch
Low
BLL
Bit 0
Bit 1
Bit 2
Bit 3
Bit 4
Bit 5
Bit 6
Bit 7
Baudrate
Divisor Latch
High
BHL
Bit 8
Bit 9
Bit 10
Bit 11
Bit 12
Bit 13
Bit 14
Bit 15
BDLAB = 1
+1
BDLAB = 1
*: Bit 0 is the least significant bit. The least significant bit is the first bit serially transmitted or received.
**: These bits are always 0 in 16450 Mode.
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Revision 0.62
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PRELIMINARY
Bit 4: EPE. This bit describes the number of logic 1's in the data word bits and parity bit only when bit 3 is
programmed. When this bit is set, an even number of logic 1's are sent or checked. When the bit
is reset, an odd number of logic 1's are sent or checked.
Bit 3: PBE. When this bit is set, the position between the last data bit and the stop bit of the SOUT will be
stuffed with the parity bit at the transmitter. For the receiver, the parity bit in the same position as
the transmitter will be detected.
Bit 2: MSBE. This bit defines the number of stop bits in each serial character that is transmitted or
received.
(1) If MSBE is set to a logical 0, one stop bit is sent and checked.
(2) If MSBE is set to a logical 1, and data length is 5 bits, one and a half stop bits are sent and
checked.
(3) If MSBE is set to a logical 1, and data length is 6, 7, or 8 bits, two stop bits are sent and
checked.
Bits 0 and 1: DLS0, DLS1. These two bits define the number of data bits that are sent or checked in
each serial character.
TABLE 3-2 WORD LENGTH DEFINITION
DLS1
DLS0
DATA LENGTH
0
0
5 bits
0
1
6 bits
1
0
7 bits
1
1
8 bits
3.2.2 UART Status Register (USR) (Read/Write)
This 8-bit register provides information about the status of the data transfer during communication.
7
6
5
4
3
2
1
0
RBR Data ready (RDR)
Overrun error (OER)
Parity bit error (PBER)
No stop bit error (NSER)
Silent byte detected (SBD)
Transmitter Buffer Register empty (TBRE)
Transmitter Shift Register empty (TSRE)
RX FIFO Error Indication (RFEI)
Bit 7: RFEI. In 16450 mode, this bit is always set to a logic 0. In 16550 mode, this bit is set to a logic 1
when there is at least one parity bit error, no stop bit error or silent byte detected in the FIFO. In
16550 mode, this bit is cleared by reading from the USR if there are no remaining errors left in
the FIFO.
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Revision 0.62
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PRELIMINARY
Bit 6: TSRE. In 16450 mode, when TBR and TSR are both empty, this bit will be set to a logical 1. In
16550 mode, if the transmit FIFO and TSR are both empty, it will be set to a logical 1. Other
thanthese two cases, this bit will be reset to a logical 0.
Bit 5: TBRE. In 16450 mode, when a data character is transferred from TBR to TSR, this bit will be set to
a logical 1. If ETREI of ICR is a logical 1, an interrupt will be generated to notify the CPU to write
the next data. In 16550 mode, this bit will be set to a logical 1 when the transmit FIFO is empty. It
will be reset to a logical 0 when the CPU writes data into TBR or FIFO.
Bit 4: SBD. This bit is set to a logical 1 to indicate that received data are kept in silent state for a full word
time, including start bit, data bits, parity bit, and stop bits. In 16550 mode, it indicates the same
condition for the data on top of the FIFO. When the CPU reads USR, it will clear this bit to a
logical 0.
Bit 3: NSER. This bit is set to a logical 1 to indicate that the received data have no stop bit. In 16550
mode, it indicates the same condition for the data on top of the FIFO. When the CPU reads USR,
it will clear this bit to a logical 0.
Bit 2: PBER. This bit is set to a logical 1 to indicate that the parity bit of received data is wrong. In 16550
mode, it indicates the same condition for the data on top of the FIFO. When the CPU reads USR,
it will clear this bit to a logical 0.
Bit 1: OER. This bit is set to a logical 1 to indicate received data have been overwritten by the next
received data before they were read by the CPU. In 16550 mode, it indicates the same condition
instead of FIFO full. When the CPU reads USR, it will clear this bit to a logical 0.
Bit 0: RDR. This bit is set to a logical 1 to indicate received data are ready to be read by the CPU in the
RBR or FIFO. After no data are left in the RBR or FIFO, the bit will be reset to a logical 0.
3.2.3 Handshake Control Register (HCR) (Read/Write)
This register controls the pins of the UART used for handshaking peripherals such as modem, and
controls the diagnostic mode of the UART.
7
6
5
0
0
0
4
3
2
1
0
Data terminal ready (DTR)
Request to send (RTS)
Loopback RI input
IRQ enable
Internal loopback enable
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Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
Bit 4: When this bit is set to a logical 1, the UART enters diagnostic mode by an internal loopback, as
follows:
(1) SOUT is forced to logical 1, and SIN is isolated from the communication link instead of the
TSR.
(2) Modem output pins are set to their inactive state.
(3) Modem input pins are isolated from the communication link and connect internally as DTR
(bit 0 of HCR) → DSR, RTS ( bit 1 of HCR) → CTS, Loopback RI input ( bit 2 of HCR) →
RI and IRQ enable ( bit 3 of HCR) → DCD.
Aside from the above connections, the UART operates normally. This method allows the
CPU to test the UART in a convenient way.
Bit 3: The UART interrupt output is enabled by setting this bit to a logic 1. In the diagnostic mode this bit
is internally connected to the modem control input DCD .
Bit 2: This bit is used only in the diagnostic mode. In the diagnostic mode this bit is internally connected
to the modem control input RI .
Bit 1: This bit controls the RTS output. The value of this bit is inverted and output to RTS .
Bit 0: This bit controls the DTR output. The value of this bit is inverted and output to DTR .
3.2.4 Handshake Status Register (HSR) (Read/Write)
This register reflects the current state of four input pins for handshake peripherals such as a modem
and records changes on these pins.
7
6
5
4
3
2
1
0
CTS toggling (TCTS)
DSR toggling (TDSR)
RI falling edge (FERI)
DCD toggling (TDCD)
Clear to send (CTS)
Data set ready (DSR)
Ring indicator (RI)
Data carrier detect (DCD)
Bit 7: This bit is the opposite of the DCD input. This bit is equivalent to bit 3 of HCR in loopback mode.
Bit 6: This bit is the opposite of the RI input. This bit is equivalent to bit 2 of HCR in loopback mode.
Bit 5: This bit is the opposite of the DSR input. This bit is equivalent to bit 0 of HCR in loopback mode.
Bit 4: This bit is the opposite of the CTS input. This bit is equivalent to bit 1 of HCR in loopback mode.
Bit 3: TDCD. This bit indicates that the DCD pin has changed state after HSR was read by the CPU.
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Revision 0.62
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PRELIMINARY
Bit 2: FERI. This bit indicates that the RI pin has changed from low to high state after HSR was read
by the CPU.
Bit 1: TDSR. This bit indicates that the DSR pin has changed state after HSR was read by the CPU.
Bit 0: TCTS. This bit indicates that the CTS pin has changed state after HSR was read.
3.2.5 UART FIFO Control Register (UFR) (Write only)
This register is used to control the FIFO functions of the UART.
7
6
5
4
3
2
1
0
FIFO enable
Receiver FIFO reset
Transmitter FIFO reset
DMA mode select
Reserved
Reserved
RX interrupt active level (LSB)
RX interrupt active level (MSB)
Bit 6, 7: These two bits are used to set the active level for the receiver FIFO interrupt. For example, if the
interrupt active level is set as 4 bytes, once there are more than 4 data characters in the receiver
FIFO, the interrupt will be activated to notify the CPU to read the data from the FIFO.
TABLE 3-3 FIFO TRIGGER LEVEL
BIT 7
BIT 6
RX FIFO INTERRUPT ACTIVE LEVEL (BYTES)
0
0
01
0
1
04
1
0
08
1
1
14
Bit 4, 5: Reserved
Bit 3: When this bit is programmed to logic 1, the DMA mode will change from mode 0 to mode 1 if
UFR bit 0 = 1.
Bit 2: Setting this bit to a logical 1 resets the TX FIFO counter logic to initial state. This bit will clear to a
logical 0 by itself after being set to a logical 1.
Bit 1: Setting this bit to a logical 1 resets the RX FIFO counter logic to initial state. This bit will clear to a
logical 0 by itself after being set to a logical 1.
Bit 0: This bit enables the 16550 (FIFO) mode of the UART. This bit should be set to a logical 1 before
other bits of UFR are programmed.
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Revision 0.62
W83977TF
PRELIMINARY
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Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
3.2.6 Interrupt Status Register (ISR) (Read only)
This register reflects the UART interrupt status, which is encoded by different interrupt sources into 3
bits.
7
6
5
4
0
0
3
2
1
0
0 if interrupt pending
Interrupt Status bit 0
Interrupt Status bit 1
Interrupt Status bit 2
FIFOs enabled
FIFOs enabled
Bit 7, 6: These two bits are set to a logical 1 when UFR bit 0 = 1.
Bit 5, 4: These two bits are always logic 0.
Bit 3: In 16450 mode, this bit is 0. In 16550 mode, both bit 3 and 2 are set to a logical 1 when a time-out
interrupt is pending.
Bit 2, 1: These two bits identify the priority level of the pending interrupt, as shown in the table below.
Bit 0: This bit is a logical 1 if there is no interrupt pending. If one of the interrupt sources has occurred,
this bit will be set to a logical 0.
TABLE 3-4 INTERRUPT CONTROL FUNCTION
ISR
INTERRUPT SET AND FUNCTION
Bit
3
Bit
2
Bit
1
Bit
0
Interrupt
priority
Interrupt Type
0
0
0
1
-
0
1
1
0
First
UART Receive
Status
1. OER = 1
0
1
0
0
Second
RBR Data Ready
1. RBR data ready
1. Read RBR
2. FIFO interrupt active level
reached
2. Read RBR until FIFO
data under active level
-
Interrupt Source
Clear Interrupt
No Interrupt pending
-
2. PBER =1
Read USR
3. NSER = 1 4. SBD = 1
1
1
0
0
Second
FIFO Data Timeout
Data present in RX FIFO for 4
characters period of time since last
access of RX FIFO.
Read RBR
0
0
1
0
Third
TBR Empty
TBR empty
1. Write data into TBR
2. Read ISR (if priority is
third)
0
0
0
0
Fourth
Handshake status
1. TCTS = 1
2. TDSR = 1
3. FERI = 1
4. TDCD = 1
Read HSR
** Bit 3 of ISR is enabled when bit 0 of UFR is logical 1.
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Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
3.2.7 Interrupt Control Register (ICR) (Read/Write)
This 8-bit register allows the five types of controller interrupts to activate the interrupt output signal
separately. The interrupt system can be totally disabled by resetting bits 0 through 3 of the Interrupt
Control Register (ICR). A selected interrupt can be enabled by setting the appropriate bits of this
register to a logical 1.
7
6
5
4
0
0
0
0
3
2
1
0
RBR data ready interrupt enable (ERDRI)
TBR empty interrupt enable (ETBREI)
UART receive status interrupt enable (EUSRI)
Handshake status interrupt enable (EHSRI)
Bit 7-4: These four bits are always logic 0.
Bit 3: EHSRI. Setting this bit to a logical 1 enables the handshake status register interrupt.
Bit 2: EUSRI. Setting this bit to a logical 1 enables the UART status register interrupt.
Bit 1: ETBREI. Setting this bit to a logical 1 enables the TBR empty interrupt.
Bit 0: ERDRI. Setting this bit to a logical 1 enables the RBR data ready interrupt.
3.2.8 Programmable Baud Generator (BLL/BHL) (Read/Write)
Two 8-bit registers, BLL and BHL, compose a programmable baud generator
that uses 24 MHz to
16
generate a 1.8461 MHz frequency and divides it by a divisor from 1 to 2 -1. The output frequency of
the baud generator is the baud rate multiplied by 16, and this is the base frequency for the transmitter
and receiver. The table in the next page illustrates the use of the baud generator with a frequency of
1.8461 MHz. In high-speed UART mode (refer to CR0C bit7 and CR0C bit6), the programmable baud
generator directly uses 24 MHz and the same divisor as the normal speed divisor. In high-speed mode,
the data transmission rate can be as high as 1.5M bps.
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PRELIMINARY
3.2.9 User-defined Register (UDR) (Read/Write)
This is a temporary register that can be accessed and defined by the user.
TABLE 3-5 BAUD RATE TABLE
Pre-Div: 13
1.8461M Hz
50
BAUD RATE FROM DIFFERENT PRE-DIVIDER
Pre-Div:1.625
Pre-Div: 1.0
Decimal divisor used
Error Percentage between
to
generate
16X
clock
desired and actual
14.769M Hz
24M Hz
400
650
2304
**
75
600
975
1536
**
110
880
1430
1047
0.18%
134.5
1076
1478.5
857
0.099%
150
1200
1950
768
**
300
2400
3900
384
**
600
4800
7800
192
**
1200
9600
15600
96
**
1800
14400
23400
64
**
2000
16000
26000
58
0.53%
2400
19200
31200
48
**
3600
28800
46800
32
**
4800
38400
62400
24
**
7200
57600
93600
16
**
9600
76800
124800
12
**
19200
153600
249600
6
**
38400
307200
499200
3
**
57600
460800
748800
2
**
115200
921600
1497600
1
**
** The percentage error for all baud rates, except where indicated otherwise, is 0.16%.
Note. Pre-Divisor is determined by CRF0 of UART A and B.
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Revision 0.62
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PRELIMINARY
4. INFRARED (IR) PORT
The Infrared (IR) function provides point-to-point (or multi-point to multi-point) wireless
communication which can operate under various transmission protocols including IrDA 1.0 SIR,
SHARP ASK-IR. IR port shares the same port with UART B port in W83977TF. Please refer to
section 11.5 for configuration information.
5. PARALLEL PORT
5.1
Printer Interface Logic
The parallel port of the W83977TF makes possible the attachment of various devices that accept
eight bits of parallel data at standard TTL level. The W83977TF supports an IBM XT/AT compatible
parallel port (SPP), bi-directional parallel port (BPP), Enhanced Parallel Port (EPP), Extended
Capabilities Parallel Port (ECP), Extension FDD mode (EXTFDD), Extension 2FDD mode
(EXT2FDD) on the parallel port. Refer to the configuration registers for more information on
disabling, power-down, and on selecting the mode of operation.
Table 5-1 shows the pin definitions for different modes of the parallel port.
TABLE 5-1-1 PARALLEL PORT CONNECTOR AND PIN DEFINITIONS
HOST
CONNECTOR
PIN NUMBER
OF W83977TF
PIN
ATTRIBUTE
SPP
EPP
ECP
1
36
O
nSTB
nWrite
2-9
31-26, 24-23
I/O
PD<0:7>
PD<0:7>
10
22
I
nACK
Intr
nACK, PeriphClk2
11
21
I
BUSY
nWait
BUSY, PeriphAck2
12
19
I
PE
PE
13
18
I
SLCT
Select
SLCT, Xflag2
14
35
O
nAFD
nDStrb
nAFD, HostAck2
15
34
I
nERR
nError
nFault1, nPeriphRequest2
16
33
O
nINIT
nInit
17
32
O
nSLIN
nAStrb
nSTB, HostClk 2
PD<0:7>
PEerror, nAckReverse2
nINIT1, nReverseRqst2
nSLIN1 , ECPMode2
Notes:
n<name > : Active Low
1. Compatible Mode
2. High Speed Mode
3. For more information, refer to the IEEE 1284 standard.
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PRELIMINARY
TABLE 5-1-2 PARALLEL PORT CONNECTOR AND PIN DEFINITIONS
HOST
CONNECTOR
PIN NUMBER OF
W83977TF
1
2
5.2
PIN
ATTRIBUTE
SPP
PIN
ATTRIBUTE
EXT2FDD
PIN
ATTRIBUTE
EXTFDD
36
O
nSTB
---
---
---
---
31
I/O
PD0
I
INDEX 2
I
INDEX 2
3
30
I/O
PD1
I
4
29
I/O
PD2
I
5
28
I/O
PD3
I
6
27
I/O
PD4
I
7
26
I/O
PD5
---
8
24
I/O
PD6
OD
9
23
I/O
PD7
OD
10
22
I
nACK
OD
11
21
I
BUSY
OD
12
19
I
PE
OD
13
18
I
SLCT
OD
14
35
O
nAFD
OD
15
34
I
nERR
OD
16
33
O
nINIT
OD
17
32
O
nSLIN
OD
TRAK02
WP2
RDATA2
DSKCHG2
--MOA 2
DSA2
DSB2
MOB2
WD2
WE2
RWC2
HEAD2
DIR2
STEP 2
I
I
I
I
TRAK02
WP2
RDATA2
DSKCHG2
---
---
---
---
---
---
OD
OD
OD
OD
OD
OD
OD
OD
DSB2
MOB2
WD2
WE2
RWC2
HEAD2
DIR2
STEP 2
Enhanced Parallel Port (EPP)
TABLE 5-2 PRINTER MODE AND EPP REGISTER ADDRESS
A2
0
0
0
0
0
1
1
1
1
A1
0
0
1
1
1
0
0
1
1
A0
0
1
0
0
1
0
1
0
1
REGISTER
Data port (R/W)
Printer status buffer (Read)
Printer control latch (Write)
Printer control swapper (Read)
EPP address port (R/W)
EPP data port 0 (R/W)
EPP data port 1 (R/W)
EPP data port 2 (R/W)
EPP data port 2 (R/W)
NOTE
1
1
1
1
2
2
2
2
2
Notes:
1. These registers are available in all modes.
2. These registers are available only in EPP mode.
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5.2.1 Data Swapper
The system microprocessor can read the contents of the printer's data latch by reading the data
swapper.
5.2.2 Printer Status Buffer
The system microprocessor can read the printer status by reading the address of the printer status
buffer. The bit definitions are as follows:
7
6
5
4
3
2
1
1
1
0
TMOUT
ERROR
SLCT
PE
ACK
BUSY
Bit 7: This signal is active during data entry, when the printer is off-line during printing, when the print
head is changing position, or during an error state. When this signal is active, the printer is
busy and cannot accept data.
Bit 6: This bit represents the current state of the printer's ACK signal. A 0 means the printer has
received a character and is ready to accept another. Normally, this signal will be active for
approximately 5 microseconds before BUSY stops.
Bit 5: Logical 1 means the printer has detected the end of paper.
Bit 4: Logical 1 means the printer is selected.
Bit 3: Logical 0 means the printer has encountered an error condition.
Bit 1, 2: These two bits are not implemented and are logic one during a read of the status register.
Bit 0: This bit is valid in EPP mode only. It indicates that a 10 µS time-out has occurred on the EPP
bus. A logic 0 means that no time-out error has occurred; a logic 1 means that a time-out error
has been detected. Writing a logic 1 to this bit will clear the time-out status bit; writing a logic 0
has no effect.
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5.2.3 Printer Control Latch and Printer Control Swapper
The system microprocessor can read the contents of the printer control latch by reading the printer
control swapper. Bit definitions are as follows:
7
6
1
1
5
4
3
2
1
0
STROBE
AUTO FD
INIT
SLCT IN
IRQ ENABLE
DIR
Bit 7, 6: These two bits are a logic one during a read. They can be written.
Bit 5: Direction control bit
When this bit is a logic 1, the parallel port is in input mode (read); when it is a logic 0, the
parallel port is in output mode (write). This bit can be read and written. In SPP mode, this bit
is invalid and fixed at zero.
Bit 4: A 1 in this position allows an interrupt to occur when ACK changes from low to high.
Bit 3: A 1 in this bit position selects the printer.
Bit 2: A 0 starts the printer (50 microsecond pulse, minimum).
Bit 1: A 1 causes the printer to line-feed after a line is printed.
Bit 0: A 0.5 microsecond minimum high active pulse clocks data into the printer. Valid data must be
present for a minimum of 0.5 microseconds before and after the strobe pulse.
5.2.4 EPP Address Port
The address port is available only in EPP mode. Bit definitions are as follows:
7
6
5
4
3
2
1
0
PD0
PD1
PD2
PD3
PD4
PD5
PD6
PD7
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The contents of DB0-DB7 are buffered (non-inverting) and output to ports PD0-PD7 during a write
operation. The leading edge of IOW causes an EPP address write cycle to be performed, and the
trailing edge of IOW latches the data for the duration of the EPP write cycle.
PD0-PD7 ports are read during a read operation. The leading edge of IOR causes an EPP address
read cycle to be performed and the data to be output to the host CPU.
5.2.5 EPP Data Port 0-3
These four registers are available only in EPP mode. Bit definitions of each data port are as follows:
7
6
5
4
3
2
1
0
PD0
PD1
PD2
PD3
PD4
PD5
PD6
PD7
When accesses are made to any EPP data port, the contents of DB0-DB7 are buffered (noninverting) and output to the ports PD0-PD7 during a write operation. The leading edge of IOW causes
an EPP data write cycle to be performed, and the trailing edge of IOW latches the data for the
duration of the EPP write cycle.
During a read operation, ports PD0-PD7 are read, and the leading edge of IOR causes an EPP read
cycle to be performed and the data to be output to the host CPU.
5.2.6 Bit Map of Parallel Port and EPP Registers
REGISTER
7
6
5
4
3
2
1
0
PD7
PD6
PD
5
PD4
PD3
PD2
PD1
PD0
BUSY
ACK
PE
SLCT
ERROR
1
1
TMOUT
Control Swapper (Read)
1
1
1
IRQEN
SLIN
INIT
AUTOFD
STROBE
Control Latch (Write)
1
1
DIR
IRQ
SLIN
INIT
AUTOFD
STROBE
EPP Address Port R/W)
PD7
PD6
PD
5
PD4
PD3
PD2
PD1
PD0
EPP Data Port 0 (R/W)
PD7
PD6
PD
5
PD4
PD3
PD2
PD1
PD0
EPP Data Port 1 (R/W)
PD7
PD6
PD
5
PD4
PD3
PD2
PD1
PD0
Data Port (R/W)
Status Buffer (Read)
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PRELIMINARY
EPP Data Port 2 (R/W)
PD7
PD6
PD
5
PD4
PD3
PD2
PD1
PD0
EPP Data Port 3 (R/W)
PD7
PD6
PD
5
PD4
PD3
PD2
PD1
PD0
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PRELIMINARY
5.2.7 EPP Pin Descriptions
EPP NAME
TYPE
EPP DESCRIPTION
nWrite
O
Denotes an address or data read or write operation.
PD<0:7>
I/O
Bi-directional EPP address and data bus.
Intr
I
Used by peripheral device to interrupt the host.
nWait
I
Inactive to acknowledge that data transfer is completed. Active to
indicate that the device is ready for the next transfer.
PE
I
Paper end; same as SPP mode.
Select
I
Printer selected status; same as SPP mode.
nDStrb
O
This signal is active low. It denotes a data read or write operation.
nError
I
Error; same as SPP mode.
nInits
O
This signal is active low. When it is active, the EPP device is reset to its
initial operating mode.
nAStrb
O
This signal is active low. It denotes an address read or write operation.
5.2.8 EPP Operation
When the EPP mode is selected in the configuration register, the standard and bi-directional modes
are also available. The PDx bus is in the standard or bi-directional mode when no EPP read, write, or
address cycle is currently being executed. In this condition all output signals are set by the SPP
Control Port and the direction is controlled by DIR of the Control Port.
A watchdog timer is required to prevent system lockup. The timer indicates that more than 10 µS
have elapsed from the start of the EPP cycle to the time WAIT is deasserted. The current EPP cycle
is aborted when a time-out occurs. The time-out condition is indicated in Status bit 0.
5.2.8.1 EPP Operation
The EPP operates on a two-phase cycle. First, the host selects the register within the device for
subsequent operations. Second, the host performs a series of read and/or write byte operations to the
selected register. Four operations are supported on the EPP: Address Write, Data Write, Address
Read, and Data Read. All operations on the EPP device are performed asynchronously.
5.2.8.2 EPP Version 1.9 Operation
The EPP read/write operation can be completed under the following conditions:
a. If the nWait is active low, when the read cycle (nWrite inactive high, nDStrb/nAStrb active low) or
write cycle (nWrite active low, nDStrb/nAStrb active low) starts, the read/write cycle proceeds
normally and will be completed when nWait goes inactive high.
b. If nWait is inactive high, the read/write cycle will not start. It must wait until nWait changes to
active low, at which time it will start as described above.
5.2.8.3 EPP Version 1.7 Operation
The EPP read/write cycle can start without checking whether nWait is active or inactive. Once the
read/write cycle starts, however, it will not terminate until nWait changes from active low to inactive
high.
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5.3 Extended Capabilities Parallel (ECP) Port
This port is software and hardware compatible with existing parallel ports, so it may be used as a
standard printer mode if ECP is not required. It provides an automatic high burst-bandwidth channel
that supports DMA for ECP in both the forward (host to peripheral) and reverse (peripheral to host)
directions.
Small FIFOs are used in both forward and reverse directions to improve the maximum bandwidth
requirement. The size of the FIFO is 16 bytes. The ECP port supports an automatic handshake for
the standard parallel port to improve compatibility mode transfer speed.
The ECP port supports run-length-encoded (RLE) decompression (required) in hardware.
Compression is accomplished by counting identical bytes and transmitting an RLE byte that indicates
how many times the next byte is to be repeated. Hardware support for compression is optional.
For more information about the ECP Protocol, refer to the Extended Capabilities Port Protocol and
ISA Interface Standard.
5.3.1 ECP Register and Mode Definitions
NAME
ADDRESS
I/O
ECP MODES
FUNCTION
data
Base+000h
R/W
000-001
ecpAFifo
Base+000h
R/W
011
ECP FIFO (Address)
dsr
Base+001h
R
All
Status Register
dcr
Base+002h
R/W
All
Control Register
cFifo
Base+400h
R/W
010
Parallel Port Data FIFO
ecpDFifo
Base+400h
R/W
011
ECP FIFO (DATA)
tFifo
Base+400h
R/W
110
Test FIFO
cnfgA
Base+400h
R
111
Configuration Register A
cnfgB
Base+401h
R/W
111
Configuration Register B
ecr
Base+402h
R/W
All
Extended Control Register
Data Register
Note: The base addresses are specified by CR60 and 61, which are determined by configuration register or hardware setting.
MODE
DESCRIPTION
000
SPP mode
001
PS/2 Parallel Port mode
010
Parallel Port Data FIFO mode
011
ECP Parallel Port mode
100
EPP mode (If this option is enabled in the CRF0 to select ECP/EPP mode)
101
Reserved
110
Test mode
111
Configuration mode
Note: The mode selection bits are bit 7-5 of the Extended Control Register.
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5.3.2 Data and ecpAFifo Port
Modes 000 (SPP) and 001 (PS/2) (Data Port)
During a write operation, the Data Register latches the contents of the data bus on the rising edge of
the input. The contents of this register are output to the PD0-PD7 ports. During a read operation,
ports PD0-PD7 are read and output to the host. The bit definitions are as follows:
7
6
5
4
3
2
1
0
PD0
PD1
PD2
PD3
PD4
PD5
PD6
PD7
Mode 011 (ECP FIFO-Address/RLE)
A data byte written to this address is placed in the FIFO and tagged as an ECP Address/RLE. The
hardware at the ECP port transmits this byte to the peripheral automatically. The operation of this
register is defined only for the forward direction. The bit definitions are as follows:
7
6
5
4
3
2
1
0
Address or RLE
Address/RLE
5.3.3 Device Status Register (DSR)
These bits are at low level during a read of the Printer Status Register. The bits of this status register
are defined as follows:
7
6
5
4
3
2
1
1
1
0
1
nFault
Select
PError
nAck
nBusy
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Bit 7: This bit reflects the complement of the Busy input.
Bit 6: This bit reflects the nAck input.
Bit 5: This bit reflects the PError input.
Bit 4: This bit reflects the Select input.
Bit 3: This bit reflects the nFault input.
Bit 2-0: These three bits are not implemented and are always logic one during a read.
5.3.4 Device Control Register (DCR)
The bit definitions are as follows:
7
1
6
5
4
3
2
1
0
1
strobe
autofd
nInit
SelectIn
ackIntEn
Direction
Bit 6, 7: These two bits are logic one during a read and cannot be written.
Bit 5: This bit has no effect and the direction is always out if mode = 000 or mode = 010. Direction is
valid in all other modes.
0
the parallel port is in output mode.
1
the parallel port is in input mode.
Bit 4: Interrupt request enable. When this bit is set to a high level, it may be used to enable interrupt
requests from the parallel port to the CPU due to a low to high transition on the ACK input.
Bit 3: This bit is inverted and output to the SLIN output.
0
The printer is not selected.
1
The printer is selected.
Bit 2: This bit is output to the INIT output.
Bit 1: This bit is inverted and output to the AFD output.
Bit 0: This bit is inverted and output to the STB output.
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5.3.5 cFifo (Parallel Port Data FIFO) Mode = 010
This mode is defined only for the forward direction. The standard parallel port protocol is used by a
hardware handshake to the peripheral to transmit bytes written or DMAed from the system to this
FIFO. Transfers to the FIFO are byte aligned.
5.3.6 ecpDFifo (ECP Data FIFO) Mode = 011
When the direction bit is 0, bytes written or DMAed from the system to this FIFO are transmitted by a
hardware handshake to the peripheral using the ECP parallel port protocol. Transfers to the FIFO are
byte aligned.
When the direction bit is 1, data bytes from the peripheral are read under automatic hardware
handshake from ECP into this FIFO. Reads or DMAs from the FIFO will return bytes of ECP data to
the system.
5.3.7 tFifo (Test FIFO Mode) Mode = 110
Data bytes may be read, written, or DMAed to or from the system to this FIFO in any direction. Data
in the tFIFO will not be transmitted to the parallel port lines. However, data in the tFIFO may be
displayed on the parallel port data lines.
5.3.8 cnfgA (Configuration Register A) Mode = 111
This register is a read-only register. When it is read, 10H is returned. This indicates to the system that
this is an 8-bit implementation.
5.3.9
cnfgB (Configuration Register B) Mode = 111
The bit definitions are as follows:
7
6
5
4
3
2
1
0
1
1
1
IRQx 0
IRQx 1
IRQx 2
intrValue
compress
Bit 7: This bit is read-only. It is at low level during a read. This means that this chip does not support
hardware RLE compression.
Bit 6: Returns the value on the ISA IRQ line to determine possible conflicts.
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Bit 5-3: Reflect the IRQ resource assigned for ECP port.
cnfgB[5:3]
000
001
010
011
100
101
110
111
IRQ resource
reflect other IRQ resources selected by PnP register (default)
IRQ7
IRQ9
IRQ10
IRQ11
IRQ14
IRQ15
IRQ5
Bit 2-0: These five bits are at high level during a read and can be written.
5.3.10
ecr (Extended Control Register) Mode = all
This register controls the extended ECP parallel port functions. The bit definitions are follows:
7
6
5
4
3
2
1
0
empty
full
service Intr
dmaEn
nErrIntrEn
MODE
MODE
MODE
Bit 7-5: These bits are read/write and select the mode.
000
001
010
011
100
101
110
111
Standard Parallel Port mode. The FIFO is reset in this mode.
PS/2 Parallel Port mode. This is the same as 000 except that direction may be
used to tri-state the data lines and reading the data register returns the value on the
data lines and not the value in the data register.
Parallel Port FIFO mode. This is the same as 000 except that bytes are written or
DMAed to the FIFO. FIFO data are automatically transmitted using the standard
parallel port protocol. This mode is useful only when direction is 0.
ECP Parallel Port Mode. When the direction is 0 (forward direction), bytes placed
into the ecpDFifo and bytes written to the ecpAFifo are placed in a single FIFO and
auto transmitted to the peripheral using ECP Protocol. When the direction is 1
(reverse direction), bytes are moved from the ECP parallel port and packed into
bytes in the ecpDFifo.
Selects EPP Mode. In this mode, EPP is activated if the EPP mode is selected.
Reserved.
Test Mode. The FIFO may be written and read in this mode, but the data will not be
transmitted on the parallel port.
Configuration Mode. The confgA and confgB registers are accessible at 0x400 and
0x401 in this mode.
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Bit 4: Read/Write (Valid only in ECP Mode)
1
Disables the interrupt generated on the asserting edge of nFault.
0
Enables an interrupt pulse on the high to low edge of nFault. If nFault is asserted
(interrupt) an interrupt will be generated and this bit is written from a 1 to 0.
Bit 3: Read/Write
1
Enables DMA.
0
Disables DMA unconditionally.
Bit 2: Read/Write
1
Disables DMA and all of the service interrupts.
0
Enables one of the following cases of interrupts. When one of the service interrupts
has occurred, the serviceIntr bit is set to a 1 by hardware. This bit must be reset to
0 to re-enable the interrupts. Writing a 1 to this bit will not cause an interrupt.
(a) dmaEn = 1: During DMA this bit is set to a 1 when terminal count is reached.
(b) dmaEn = 0 direction = 0: This bit is set to 1 whenever there are writeIntr
Threshold or more bytes free in the FIFO.
(c) dmaEn = 0 direction = 1: This bit is set to 1 whenever there are readIntr
Threshold or more valid bytes to be read from the FIFO.
Bit 1: Read only
0
The FIFO has at least 1 free byte.
1
The FIFO cannot accept another byte or the FIFO is completely full.
Bit 0: Read only
0
The FIFO contains at least 1 byte of data.
1
The FIFO is completely empty.
5.3.11
Bit Map of ECP Port Registers
data
ecpAFifo
dsr
dcr
cFifo
ecpDFifo
tFifo
cnfgA
cnfgB
ecr
D7
D6
D5
D4
D3
D2
D1
D0
PD7
PD6
PD5
PD4
PD3
PD2
PD1
PD0
Addr/RLE
Address or RLE field
NOTE
2
nBusy
nAck
PError
Select
nFault
1
1
1
1
1
1
Directio
ackIntEn
SelectIn
nInit
autofd
strobe
1
Parallel Port Data FIFO
2
ECP Data FIFO
2
Test FIFO
0
compress
2
0
0
intrValue
1
MODE
1
0
0
0
0
1
1
1
1
1
nErrIntrEn
dmaEn
serviceIntr
full
empty
Notes:
1. These registers are available in all modes.
2. All FIFOs use one common 16-byte FIFO.
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5.3.12
ECP Pin Descriptions
NAME
TYPE
DESCRIPTION
nStrobe (HostClk)
O
The nStrobe registers data or address into the slave on the
asserting edge during write operations. This signal handshakes
with Busy.
PD<7:0>
I/O
These signals contains address or data or RLE data.
nAck (PeriphClk)
I
This signal indicates valid data driven by the peripheral when
asserted. This signal handshakes with nAutoFd in reverse.
Busy (PeriphAck)
I
This signal deasserts to indicate that the peripheral can accept
data. It indicates whether the data lines contain ECP command
information or data in the reverse direction. When in reverse
direction, normal data are transferred when Busy (PeriphAck)
is high and an 8-bit command is transferred when it is low.
PError (nAckReverse)
I
This signal is used to acknowledge a change in the direction of
the transfer (asserted = forward). The peripheral drives this
signal low to acknowledge nReverseRequest. The host relies
upon nAckReverse to determine when it is permitted to drive
the data bus.
Select (Xflag)
I
Indicates printer on line.
nAutoFd (HostAck)
O
Requests a byte of data from the peripheral when it is asserted.
This signal indicates whether the data lines contain ECP
address or data in the forward direction. When in forward
direction, normal data are transferred when nAutoFd (HostAck)
is high and an 8-bit command is transferred when it is low.
nFault (nPeriphRequest)
I
Generates an error interrupt when it is asserted. This signal is
valid only in the forward direction. The peripheral is permitted
(but not required) to drive this pin low to request a reverse
transfer during ECP Mode.
nInit (nReverseRequest)
O
This signal sets the transfer direction (asserted = reverse,
deasserted = forward). This pin is driven low to place the
channel in the reverse direction.
nSelectIn (ECPMode)
O
This signal is always deasserted in ECP mode.
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5.3.13
ECP Operation
The host must negotiate on the parallel port to determine if the peripheral supports the ECP protocol
before ECP operation. After negotiation, it is necessary to initialize some of the port bits. The
following are required:
(a) Set direction = 0, enabling the drivers.
(b) Set strobe = 0, causing the nStrobe signal to default to the deasserted state.
(c) Set autoFd = 0, causing the nAutoFd signal to default to the deasserted state.
(d) Set mode = 011 (ECP Mode)
ECP address/RLE bytes or data bytes may be sent automatically by writing the ecpAFifo or ecpDFifo,
respectively.
5.3.13.1 Mode Switching
Software will execute P1284 negotiation and all operations prior to a data transfer phase under
programmed I/O control (mode 000 or 001). Hardware provides an automatic control line handshake,
moving data between the FIFO and the ECP port only in the data transfer phase (mode 011 or 010).
If the port is in mode 000 or 001 it may switch to any other mode. If the port is not in mode 000 or 001
it can only be switched into mode 000 or 001. The direction can be changed only in mode 001.
When in extended forward mode, the software should wait for the FIFO to be empty before switching
back to mode 000 or 001. In ECP reverse mode the software waits for all the data to be read from the
FIFO before changing back to mode 000 or 001.
5.3.13.2 Command/Data
ECP mode allows the transfer of normal 8-bit data or 8-bit commands. In the forward direction,
normal data are transferred when HostAck is high and an 8-bit command is transferred when HostAck
is low. The most significant bits of the command indicate whether it is a run-length count (for
compression) or a channel address.
In the reverse direction, normal data are transferred when PeriphAck is high and an 8-bit command is
transferred when PeriphAck is low. The most significant bit of the command is always zero.
5.3.13.3 Data Compression
The W83977TF supports run length encoded (RLE) decompression in hardware and can transfer
compressed data to a peripheral. Note that the odd (RLE) compression in hardware is not supported.
In order to transfer data in ECP mode, the compression count is written to the ecpAFifo and the data
byte is written to the ecpDFifo.
5.3.14
FIFO Operation
The FIFO threshold is set in configuration register 5. All data transfers to or from the parallel port can
proceed in DMA or Programmed I/O (non-DMA) mode, as indicated by the selected mode. The FIFO
is used by selecting the Parallel Port FIFO mode or ECP Parallel Port Mode. After a reset, the FIFO
is disabled.
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5.3.15
DMA Transfers
DMA transfers are always to or from the ecpDFifo, tFifo, or CFifo. The DMA uses the standard PC
DMA services. The ECP requests DMA transfers from the host by activating the PDRQ pin. The DMA
will empty or fill the FIFO using the appropriate direction and mode. When the terminal count in the
DMA controller is reached, an interrupt is generated and serviceIntr is asserted, which will disable the
DMA.
5.3.16
Programmed I/O (NON-DMA) Mode
The ECP or parallel port FIFOs can also be operated using interrupt driven programmed I/O.
Programmed I/O transfers are to the ecpDFifo at 400H and ecpAFifo at 000H or from the ecpDFifo
located at 400H, or to/from the tFifo at 400H. The host must set the direction, state, dmaEn = 0 and
serviceIntr = 0 in the programmed I/O transfers.
The ECP requests programmed I/O transfers from the host by activating the IRQ pin. The
programmed I/O will empty or fill the FIFO using the appropriate direction and mode.
5.4
Extension FDD Mode (EXTFDD)
In this mode, the W83977TF changes the printer interface pins to FDC input/output pins, allowing the
user to install a second floppy disk drive (FDD B) through the DB-25 printer connector. The pin
assignments for the FDC input/output pins are shown in Table 5-1.
After the printer interface is set to EXTFDD mode, the following occur:
(1) Pins MOB and DSB will be forced to inactive state.
(2) Pins DSKCHG , RDATA , WP , TRAK0 , INDEX will be logically ORed with pins PD4-PD0 to serve
as input signals to the FDC.
(3) Pins PD4-PD0 each will have an internal resistor of about 1K ohm to serve as pull-up resistor for
FDD open drain/collector output.
(4) If the parallel port is set to EXTFDD mode after the system has booted DOS or another operating
system, a warm reset is needed to enable the system to recognize the extension floppy drive.
5.5
Extension 2FDD Mode (EXT2FDD)
In this mode, the W83977TF changes the printer interface pins to FDC input/output pins, allowing the
user to install two external floppy disk drives through the DB-25 printer connector to replace internal
floppy disk drives A and B. The pin assignments for the FDC input/output pins are shown in Table5-1.
After the printer interface is set to EXTFDD mode, the following occur:
(1) Pins MOA , DSA , MOB , and DSB will be forced to inactive state.
(2) Pins DSKCHG, RDATA , WP, TRAK0, and INDEX will be logically ORed with pins PD4-PD0 to
serve as input signals to the FDC.
(3) Pins PD4-PD0 each will have an internal resistor of about 1K ohm to serve as pull-up resistor for
FDD open drain/collector output.
(4) If the parallel port is set to EXT2FDD mode after the system has booted DOS or another operating
system, a warm reset is needed to enable the system to recognize the extension floppy drive.
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PRELIMINARY
6. KEYBOARD CONTROLLER
The KBC (8042 with licensed KB BIOS) circuit of W83977TF is designed to provide the functions
needed to interface a CPU with a keyboard and/or a PS/2 mouse, and can be used with IBMcompatible personal computers or PS/2-based systems. The controller receives serial data from the
keyboard or PS/2 mouse, checks the parity of the data, and presents the data to the system as a byte
of data in its output buffer. Then, the controller will assert an interrupt to the system when data are
placed in its output buffer. The keyboard and PS/2 mouse are required to acknowledge all data
transmissions. No transmission should be sent to the keyboard or PS/2 mouse until an acknowledge
is received for the previous data byte.
KINH
P17
8042
P24
KIRQ
P25
MIRQ
P21
GATEA20
P20
KBRST
P27
KDAT
P10
P26
KCLK
T0
GP I/O PINS
Multiplex I/O PINS
MCLK
P23
P12~P16
T1
MDAT
P22
P11
Keyboard and Mouse Interface
6.1 Output Buffer
The output buffer is an 8-bit read-only register at I/O address 60H (Default, PnP programmable I/O
address LD5-CR60 and LD5-CR61). The keyboard controller uses the output buffer to send the scan
code received from the keyboard and data bytes required by commands to the system. The output
buffer can only be read when the output buffer full bit in the register is "1".
6.2 Input Buffer
The input buffer is an 8-bit write-only register at I/O address 60H or 64H (Default, PnP programmable
I/O address LD5-CR60, LD5-CR61, LD5-CR62, and LD5-CR63). Writing to address 60H sets a flag
to indicate a data write; writing to address 64H sets a flag to indicate a command write. Data written
to I/O address 60H is sent to keyboard (unless the keyboard controller is expecting a data byte)
through the controller's input buffer only if the input buffer full bit in the status register is 0 .
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6.3 Status Register
The status register is an 8-bit read-only register at I/O address 64H (Default, PnP programmable I/O
address LD5-CR62 and LD5-CR63), that holds information about the status of the keyboard controller
and interface. It may be read at any time.
BIT
0
BIT FUNCTION
Output Buffer Full
1
Input Buffer Full
2
System Flag
3
Command/Data
4
Inhibit Switch
5
Auxiliary Device Output
Buffer
General Purpose Timeout
Parity Error
6
7
6.4
DESCRIPTION
0: Output buffer empty
1: Output buffer full
0: Input buffer empty
1: Input buffer full
This bit may be set to 0 or 1 by writing to the system flag
bit in the command byte of the keyboard controller. It
defaults to 0 after a power-on reset.
0: Data byte
1: Command byte
0: Keyboard is inhibited
1: Keyboard is not inhibited
0: Auxiliary device output buffer empty
1: Auxiliary device output buffer full
0: No time-out error
1: Time-out error
0: Odd parity
1: Even parity (error)
Commands
COMMAND
FUNCTION
20h
Read Command Byte of Keyboard Controller
60h
Write Command Byte of Keyboard Controller
BIT DEFINITION
BIT
A4h
7
Reserved
6
IBM Keyboard Translate Mode
5
Disable Auxiliary Device
4
Disable Keyboard
3
Reserve
2
System Flag
1
Enable Auxiliary Interrupt
0
Enable Keyboard Interrupt
Test Password
Returns 0Fah if Password is loaded
Returns 0F1h if Password is not loaded
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6.4 Commands, continued
COMMAND
A5h
A7h
FUNCTION
Load Password
Load Password until a "0" is received from the system
Enable Password
Enable the checking of keystrokes for a match with the password
Disable Auxiliary Device Interface
A8h
Enable Auxiliary Device Interface
A9h
Interface Test
A6h
BIT
AAh
ABh
BIT DEFINITION
00
No Error Detected
01
Auxiliary Device "Clock" line is stuck low
02
Auxiliary Device "Clock" line is stuck high
03
Auxiliary Device "Data" line is stuck low
04
Auxiliary Device "Data" line is stuck low
Self-test
Returns 055h if self test succeeds
Interface Test
BIT
00
BIT DEFINITION
No Error Detected
01
Keyboard "Clock" line is stuck low
02
Keyboard "Clock" line is stuck high
03
Keyboard "Data" line is stuck low
04
Keyboard "Data" line is stuck high
ADh
Disable Keyboard Interface
AEh
Enable Keyboard Interface
C0h
Read Input Port(P1) and send data to the system
C1h
Continuously puts the lower four bits of Port1 into STATUS register
C2h
Continuously puts the upper four bits of Port1 into STATUS register
D0h
Send Port2 value to the system
D1h
Only set/reset GateA20 line based on the system data bit 1
D2h
Send data back to the system as if it came from Keyboard
D3h
Send data back to the system as if it came from Auxiliary Device
D4h
Output next received byte of data from system to Auxiliary Device
E0h
Reports the status of the test inputs
FXh
Pulse only RC(the reset line) low for 6µS if Command byte is even
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6.5 Hardware GATEA20/Keyboard Reset Control Logic
The KBC implements a hardware control logic to speed-up GATEA20 and KBRESET. This control
logic is controlled by LD5-CRF0 as follows:
6.5.1 KB Control Register (Logic Device 5, CR-F0)
BIT
7
NAME
KCLKS1
6
5
4
3
KCLKS0 Reserved Reserved Reserved
2
1
0
P92EN
HGA20
HKBRST
KCLKS1, KCLKS0
This 2 bits are for the KBC clock rate selection.
= 0 0 KBC clock input is 6 Mhz
= 0 1 KBC clock input is 8 Mhz
= 1 0 KBC clock input is 12 Mhz
= 1 1 KBC clock input is 16 Mhz
P92EN (Port 92 Enable)
A "1" on this bit enables Port 92 to control GATEA20 and KBRESET.
A "0" on this bit disables Port 92 functions.
HGA20 (Hardware GATE A20)
A "1" on this bit selects hardware GATEA20 control logic to control GATE A20 signal.
A "0" on this bit disables hardware GATEA20 control logic function.
HKBRST (Hardware Keyboard Reset)
A "1" on this bit selects hardware KB RESET control logic to control KBRESET signal.
A "0" on this bit disables hardware KB RESET control logic function.
When the KBC receives data that follows a "D1" command, the hardware control logic sets or clears
GATE A20 according to the received data bit 1. Similarly, the hardware control logic sets or clears
KBRESET depending on the received data bit 0. When the KBC receives a "FE" command, the
KBRESET is pulse low for 6µS(Min.) with 14µS(Min.) delay.
GATEA20 and KBRESET are controlled by either the software control or the hardware control logic
and they are mutually exclusive. Then, GATEA20 and KBRESET are merged along with Port92
when P92EN bit is set.
6.5.2 Port 92 Control Register (Default Value = 0x24)
BIT
7
6
5
4
3
2
1
0
NAME
Res. (0)
Res. (0)
Res. (1)
Res. (0)
Res. (0)
Res. (1)
SGA20
PLKBRST
SGA20 (Special GATE A20 Control)
A "1" on this bit drives GATE A20 signal to high.
A "0" on this bit drives GATE A20 signal to low.
PLKBRST (Pull-Low KBRESET)
A "1" on this bit causes KBRESET to drive low for 6µS(Min.) with 14µS(Min.) delay. Before issuing
another keyboard reset command, the bit must be cleared.
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6.6
OnNow / Security Keyboard and Mouse Wake-Up
---- Programmable Keyboard / Mouse Wake-Up Functions
Winbond's unique programmable keyboard/ mouse wake-up functions provide the system diversified
methods for either OnNow wake-up application, or security control application. The keyboard or
mouse can wake up the system by producing a panel switch low pulse on PANSWOUT pin, and connect
TM
it to chipset (for example Intel
chipset TX, LX PIIX4) panel switch input. The wake-up conditions
can be programmed as pre-determined or any keys/buttons. To implement this function, a
32.768KHz crystal must be installed between XTAL1 and XTAL2, or a 32.768KHz clock to be
connected to XTAL1 and leave XTAL2 open. The VSB pin must be connected to +5V VSB of ATX
power supply, and an external battery should be installed on VBAT pin to store the data (the
passwords and wake-up status which had been set already) when power fails.
6.6.1 Keyboard Wake-Up Function
The keyboard wake-up function is enable by setting LD-0A CR-E0 bit 6. The pre-determined keys
data are stored in registers, and they can be access by an indirection method. At first, write their
index address to LD-0A CR-E1, then access them by reading/writing LD-0A CR-E2. A zero data is
written to the register means the comparison of this register will be ignored. The pre-programmed
keys may be 1 to 5 keys with various combinations. If LD-0A CR-E0 bit 0 is set, the system will be
waken up after any key struck.
6.6.2 Keyboard Password Wake-Up Function
To implement this function, the bit 7 of LD-0A CR-E0 must be set, and panel switch input is
connected to PANSWIN pin. Thus PANSWIN is blocked to PANSWOUT , by setting LD-0A CR-E0 properly
and make only keyboard can wake up the system with preset keys (password).
6.6.3 Mouse Wake-Up Function
The mouse wake-up function is activated by setting bit 5 of LD-0A CR-E0. If bit 1 of LD-0A CR-E0 is
set, any movement or button clicking will make up the system. Otherwise, the mouse can wake up
the system only by clicking its button twice successively with the mouse unmoved. The bit 4 of LD0A CR-E0 determines which button (left or right) to perform wake-up function.
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PRELIMINARY
7. GENERAL PURPOSE I/O
W83977TF provides 23 Input/Output ports that can be individually configured to perform a simple
basic I/O function or a pre-defined alternate function. Those 23 GP I/O ports are divided into three
groups, the first group contains 8 ports, the second group contains only 7 ports, and the third group
contains 8 ports. Each port in first group corresponds to a configuration register in logical device 7,
the second group in logical device 8, and the third group in logical device 9. Users can select those
I/O ports functions by independently programming those configuration registers. Figure 7.1, 7.2, and
7.3 respectively show the GP I/O port's structure of logical device 7, 8, and 9. Right after Power-on
reset, those ports default to perform basic I/O functions.
Figure 7.1
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Figure 7.2
Figure 7.3
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7.1
Basic I/O functions
The Basic I/O functions of W83977TF provide several I/O operations including driving a logic value to
output port, latching a logic value from input port, inverting the input/output logic value, and steering
Common Interrupt (only available in the second group of the GP I/O port). Common Interrupt is the
ORed function of all interrupt channels in the second group of the GP I/O ports, and it also connects
to a 1ms debounce filter which can reject a noise of 1 ms pulse width or less. There are three 8-bit
registers (GP1, GP2, and GP3) which are directly connected to those GP I/O ports. Each GP I/O port
is represented as a bit in one of three 8-bit registers. Only 6 bits of GP2 are implemented. Table
7.1.1 shows their combinations of Basic I/O functions, and Table 7.1.2 shows the register bit
assignments of GP1, GP2, and GP3.
Table 7.1.1
I/O BIT
ENABLE INT BIT
POLARITY BIT
0 = OUTPUT
0 = DISABLE
0 = NON INVERT
1 = INPUT
1 = ENABLE
1 = INVERT
0
0
0
Basic non-inverting output
0
0
1
Basic inverting output
0
1
0
Non-inverted output bit value of GP2
drive to Common Interrupt
0
1
1
Inverted output bit value of GP2 drive
to Common Interrupt
1
0
0
Basic non-inverting input
1
0
1
Basic inverting input
1
1
0
Non-inverted input drive to Common
Interrupt
1
1
1
Inverted input drive to Common
Interrupt
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PRELIMINARY
Table 7.1.2
GP I/O PORT ACCESSED
REGISTER
GP1
GP2
GP3
REGISTER BIT
ASSIGNMENT
GP I/O PORT
BIT 0
GP10
BIT 1
GP11
BIT 2
GP12
BIT 3
GP13
BIT 4
GP14
BIT 5
GP15
BIT 6
GP16
BIT 7
GP17
BIT 0
GP20
BIT 1
GP21
BIT 2
GP22
BIT 3
GP23
BIT 4
GP24
BIT 5
GP25
BIT 6
GP26
BIT 0
GP30
BIT 1
GP31
BIT 2
GP32
BIT 3
GP33
BIT 4
GP34
BIT 5
GP35
BIT 6
GP36
BIT 7
GP37
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7.2
Alternate I/O Functions
W83977TF provides several alternate functions which are scattered among the GP I/O ports. Table
7.2.1 shows their assignments. Polarity bit can also be set to alter their polarity.
Table 7.2.1
GP I/O PORT
ALTERNATE FUNCTION
GP10
Interrupt Steering
GP11
Interrupt Steering
GP12
Watch Dog Timer Output/IRRX input
GP13
Power LED output/IRTX output
GP14
General Purpose Address Decoder/Keyboard Inhibit(P17)
GP15
General Purpose Write Strobe/ 8042 P12
GP16
Watch Dog Timer Output
GP17
Power LED output
GP20
Keyboard Reset (8042 P20)
GP21
8042 P13
GP22
8042 P14
GP23
8042 P15
GP24
8042 P16
GP25
GATE A20 (8042 P21)
GP30
Interrupt Steering
GP31
Interrupt Steering
GP32
General Purpose Address Decoder
GP33
General Purpose Address Decoder
GP34
Watch Dog Timer Output
7.2.1 Interrupt Steering
GP10, GP11, GP30, and GP31 can be programmed to map their own interrupt channels. The
selection of IRQ channel can be done in configuration registers CR70 and CR72 of logical device 7
and logical device 9. Each interrupt channel also has its own 1 ms debounce filter that is used to
reject any noise whose width is equal to or less than 1 ms.
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7.2.2 Watch Dog Timer Output
Watch Dog Timer contains a one minute resolution down counter, CRF2 of Logical Device 8, and two
watch Dog control registers, WDT_CTRL0 and WDT_CTRL1 of Logical Device 8. The down counter
can be programmed within the range from 1 to 255 minutes. Writing any new non-zero value to
CRF2 or reset signal coming from a Mouse interrupt or Keyboard interrupt (CRF2 also contains nonzero value) will cause the Watch Dog Timer to reload and start to count down from the new value. As
the counter reaches zero, (1) Watch Dog Timer time-out occurs and the bit 0 of WDT_CTRL1 will be
set to logic 1; (2) Watch Dog interrupt output is asserted if the interrupt is enable in CR72 of logical
device 8; and (3) Power LED starts to toggle output if the bit 3 of WDT_CTRL0 is enabled.
WDT_CTRL1 also can be accessed through GP2 I/O base address + 1.
7.2.3 Power LED
The Power LED function provides 1 Hertz rate toggle pulse output with 50 percent duty cycle. Table
7.2.2 shows how to enable Power LED.
Table 7.2.2
WDT_CTRL1 BIT[1]
WDT_CTRL0 BIT[3]
WDT_CTRL1 BIT[0]
POWER LED STATE
1
X
X
1 Hertz Toggle pulse
0
0
X
Continuous high or low *
0
1
0
Continuous high or low *
0
1
1
1 Hertz Toggle pulse
* Note: Continuous high or low depends on the polarity bit of GP13 or GP17 configuration registers.
7.2.4 General Purpose Address Decoder
General Purpose Address Decoder provides two address decode as AEN equal to logic 0. The
address base is stored at CR62, CR63 of logical device 7 for GP14 and at CR62-65 of logical device
9 for GP32 and GP33. The decoding output is normally active low. Users can alter its polarity
through the polarity bit of the GP14, GP32, and GP33's configuration register.
7.2.5 General Purpose Write Strobe
General Purpose Write Strobe is an address decoder that performs like General Purpose Address
Decoder, but it has to be qualified by IOW and AEN. Its output is normally active low. Users can
alter its polarity through the polarity bit of the GP15's configuration register.
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8. PLUG AND PLAY CONFIGURATION
The W83977TF uses Compatible PNP protocol to access configuration registers for setting up
different types of configurations. In W83977TF, there are nine Logical Devices (from Logical Device
0 to Logical Device A with the exception of logical device 4 and 6 for compatibility) which correspond
to nine individual functions: FDC (logical device 0), PRT (logical device 1), UART1 (logical device 2),
UART2 (logical device 3), KBC (logical device 5), GPIO1 (logical device 7), GPIO2 (logical device 8),
GPIO3 (logical device 9), and ACPI ((logical device A). Each Logical Device has its own
configuration registers (above CR30). Host can access those registers by writing an appropriate
logical device number into logical device select register at CR7.
8.1
Compatible PnP
8.1.1 Extended Function Registers
In Compatible PnP, there are two ways to enter Extended Function and read or write the configuration
registers. HEFRAS (CR26 bit 6) can be used to select one out of these two methods of entering the
Extended Function mode as follows:
HEFRAS
address and value
0
write 87h to the location 3F0h twice
1
write 87h to the location 370h twice
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After Power-on reset, the value on RTSA (pin 43) is latched by HEFRAS of CR26. In Compatible
PnP, a specific value (87h) must be written twice to the Extended Functions Enable Register (I/O port
address 3F0h or 370h). Secondly, an index value (02h, 07h-FFh) must be written to the Extended
Functions Index Register (I/O port address 3F0h or 370h same as Extended Functions Enable
Register) to identify which configuration register is to be accessed. The designer can then access the
desired configuration register through the Extended Functions Data Register (I/O port address 3F1h
or 371h).
After programming of the configuration register is finished, an additional value (AAh) should be
written to EFERs to exit the Extended Function mode to prevent unintentional access to those
configuration registers. The designer can also set bit 5 of CR26 (LOCKREG) to high to protect the
configuration registers against accidental accesses.
The configuration registers can be reset to their default or hardware settings only by a cold reset (pin
MR = 1). A warm reset will not affect the configuration registers.
8.1.2 Extended Functions Enable Registers (EFERs)
After a power-on reset, the W83977TF enters the default operating mode. Before the W83977TF
enters the extended function mode, a specific value must be programmed into the Extended Function
Enable Register (EFER) so that the extended function register can be accessed. The Extended
Function Enable Registers are write-only registers. On a PC/AT system, their port addresses are
3F0h or 370h (as described in previous section).
8.1.3 Extended Function Index Registers (EFIRs), Extended Function Data Registers(EFDRs)
After the extended function mode is entered, the Extended Function Index Register (EFIR) must be
loaded with an index value (02h, 07h-FEh) to access Configuration Register 0 (CR0), Configuration
Register 7 (CR07) to Configuration Register FE (CRFE), and so forth through the Extended Function
Data Register (EFDR). The EFIRs are write-only registers with port address 3F0h or 370h (as
described in section 8.1.1) on PC/AT systems; the EFDRs are read/write registers with port address
3F1h or 371h (as described in section 8.1.1) on PC/AT systems.
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9. ACPI REGISTERS FEATURES
W83977TF supports both ACPI and legacy power managements. The switch logic of the power
managment block generates an SMI interrupt in the legacy mode and an SCI interrupt in the ACPI
mode. For the legacy mode, the SMI_EN bit is used. If it is set, it routes the power management
events to the SMI interrupt logic. For the ACPI mode, the SCI_EN bit is used. If it is set, it route the
power management events to the SCI interrupt logic. The SMI_EN bit is located in the configuration
register block of Device A and the SCI_EN bit is located in the PM1 register block. See the following
figure for illustration.
SMI_EN
IRQs
from SCI to SMI
IRQs
PM Timer
SMI Logic
0
SMI
SCI output
Logic
SCI
1
SCI_EN
from SMI to SCI
Bus Master SCI
SMI output
Logic
SCI Logic
WAK_STS
IRQs
Sleep/Wake
State machine
Device Idle
Timers
Clock
Control
Device Trap
Global STBY
Timer
The SMI interrupt is routed to pin SMI , which is dedicated for the SMI interrupt output. Another way
to output the SMI interrupt is to route to pin IRQSER, which is the signal pin in the Serial IRQ mode.
The SCI interrupt can be routed to pin SCI , which is dedicated for the SCI function. Or it can be
routed to one interrupt request pin, which is selected through CR70.bit3 - 0 of logical device 9.
Another way is to output the SCI interrupt to pin IRQSER if serial IRQ mode is enabled.
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9.1
SMI to SCI/SCI to SMI and Bus Master
The following figure illustrates the process of generating an interrupt from SMI to SCI or from SCI to
SMI .
clear
from SMI to SCI
BIOS_RLS
GBL_STS
set
To SCI Logic
GBL_EN
clear
from SCI to SMI
GBL_RLS
BIOS_STS
set
To SMI Logic
BIOS_EN
clear
BUS Master SCI
BM_CNTPL
BM_STS
set
To SCI Logic
BM_RLD
: Status bit
: Enable bit
For the BIOS software to raise an event to the ACPI software, BIOS_RLS, GBL_EN, and GBL_STS
bits are involved. GBL_EN is the enable bit and the GBL_STS is the status bit. Both are controlled
by the ACPI software. If BIOS_RLS is set by the BIOS software and GBL_EN is set by the ACPI
software, an SCI interrupt is raised. Writing a 1 to BIOS_RLS sets it to logic 1 and also sets
GBL_STS to logic 1. Writing a 0 to BIOS_RLS has no effect. Wrinting a 1 to GBL_STS clears it to
logic 0 and also clears BIOS_RLS to logic 0. Writing a 0 to GBL_STS has no effect.
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For the ACPI software to raise an event to the BIOS software, GBL_RLS, BIOS_EN, and BIOS_STS
bits are involved. BIOS_EN is the enable bit and the BIOS_STS is the status bit. Both are controlled
by the BIOS software. If GBL_RLS is set by the ACPI software and BIOS_EN is set by the BIOS
software, an SMI is raised. Writing a 1 to GBL_RLS sets it to logic 1 and also sets BIOS_STS to
logic 1. Writing a 0 to GBL_RLS has no effect. Wrinting a 1 to BIOS_STS clears it to logic 0 and
also clears GBL_RLS to logic 0. Writing a 0 to BIOS_STS has no effect.
For the bus master to raise an event to the ACPI software, BM_CNTRL, BM_RLD, and BM_STS bits
are involved. Both BM_RLD and BM_STS are controlled by the ACPI software. If BM_CNTRL is set
by the BIOS software and BM_RLD is set by the ACPI software, an SCI interrupt is raised. Writing a
1 to BM_CNTRL sets it to logic 1 and also sets BM_STS to logic 1. Writing a 0 to BM_CNTRL has no
effect. Wrinting a 1 to BM_STS clears it to logic 0 and also clears BM_CNTRL to logic 0. Writing a 0
to BM_STS has no effect.
9.2
Power Management Timer
In the ACPI specification, it requires a power management timer. The power management timer is a
24-bit fixed rate free running up-count timer that runs off a 3.579545MHZ clock. The power
management timer corresponds to status bit (TMR_STS) and enable bit (TMR_EN). The TMR_STS
bit is set any time the last bit of the timer (bit 23) goes from 0 to 1 or from 1 to 0. If the TMR_EN bit
is set, the setting of the TMR_STS bit will generate an SCI interrupt. Three registers are used to
read the timer value which are located in the PM1 register block. The power management timer has
one enabel bit (TMR_ON) to turn ii on or off. The TMR_ON is located in GPE register block. If it is
cleared to 0, the power management timer function would not work. There are no timer reset
requirements, except that the timer should function after power-up. See the following figure for
illustration.
TMR_ON
3.579545 MHz
24 bit
counter
Bits (23-0)
TMR_STS
To SCI Logic
24
TMR_EN
TMR_VAL
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9.3
ACPI Registers (ACPIRs)
The ACPI register model consists of the fixed register blocks that perform the ACPI functuions. A
register block may be a event register block which deals with ACPI events or a control register block
which deals with control features. The order in the event register block is a status register followed by
an enable register.
Each event register, if implemented, contains two two register: a status register and an enable
register, of 16 bits wide each. The status register indicates which event triggers the ACPI System
Control Interrupt ( SCI ). When the hardware event occurs, the corresponding status bit will be set.
However, the corresponding enable bit is also required to be set before an SCI interrupt could be
raised. If the enable bit is not set, the software can examine the state of the hardware event by
reading the status bit without generating an SCI interrupt.
Any status bit, unless otherwise noted, can only be set by specific hardware event. It is cleared by
writing a 1 to its bit position and writing a 0 has no effect. Except some special status bits, every
status bit has the corresponding enable bit on the same bit position in the enable register. Those
status bits which have no corresponding enable bit are read for special purpose. Reverved or
unimplemented enable bits always return zero, and writing to these bits should has no effect.
The control bit in the control register provides some special control function over the hardware event,
or some special control over SCI event. Reserved or unimplemented control bits always return zero,
and writing to those bits should has no effect.
Table 9-1 (sec. 9.3.21) lists the PM1 register block and its registers. The base address of PM1
register block is named as PM1a_EVT_BLK in the ACPI specification and is specified in CR60, 61 of
logical device A.
Table 9-2 (sec. 9.3.21) lists the GPE register block and its registers. The base address of generalpurpose event block GPE0 is named as GPE0_BLK in the ACPI specification and is specified in
CR62, 63 of logical device A. The base address of general-purpose event block GPE1 is named as
GPE1_BLK in the ACPI specification and is specified in CR64, 65 of logical device A.
9.3.1 Power Management 1 Status Register 1 (PM1STS1)
Register Location:
<CR60, 61> System I/O Space
Default Value:
00h
Attribute:
Read/write
Size:
8 bits
7
6
5
4
3
2
1
0
TMR_STS
Reserved
Reserved
Reserved
BM_STS
GBL_STS
Reserved
Reserved
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Bit
Name
Description
0
TMR_STS
This bit is the timer carry status bit. This bit is set anytime the bit 23 of the
24-bit counter changes (whenever the MSB changes from low to high or high
to low). When TMR_EN and TMR_STS are set, a power magement event is
raised. This bit is only set by hardware and can only be cleared by writing a
1 to this bit position. Writing a 0 has no effect.
1-3
4
Reserved
BM_STS
Reserved.
This is the bus master status bit. Writing a 1 to BM_CNTRL also sets
BM_STS. Writing a 1 clears this bit and also clears BM_CNTRL. Writing a
0 has no effect.
5
GBL_STS
6-7
Reserved
This is the global status bit. This bit is set when the BIOS wants the
attention of the SCI handler. BIOS sets this bit by setting BIOS_RLS and
can only be cleared by writing a 1 to this bit position. Writing a 1 to this bit
position also clears BIOS_RLS. Writing a 0 has no effect.
Reserved. These bits always return zeros.
9.3.2 Power Management 1 Status Register 2 (PM1STS2)
Register Location:
<CR60, 61> + 1H System I/O Space
Default Value:
00h
Attribute:
Read/write
Size:
8 bits
7
6
5
4
3
2
1
0
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
WAK_STS
Bit
Name
Description
0-6
Reserved
Reserved.
7
WAK_STS
This bit is set when the system is in the sleeping state and an enabled resume
event occurs. Upon setting this bit, the sleeping/working state machine will
transition the system to the working state. This bit is only set by hardware and
is cleared by writing a 1 to this bit position or by the sleeping/working state
machine automatically when the global standby timer expires. Writing a 0 has
no effect. When the WAK_STS is cleared and all devices are in sleeping
state, the whole chip enters the sleeping state.
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9.3.3 Power Management 1 Enable Register 1(PM1EN1)
Register Location:
Default Value:
Attribute:
Size:
8 bits
7
6
<CR60, 61> + 2H System I/O Space
00h
Read/write
5
4
3
2
1
0
TMR_EN
Reserved
Reserved
Reserved
GBL_EN
Reserved
Reserved
Reserved
Bit
Name
Description
0
TMR_EN
This is the timer carry interrupt enable bit. When this bit is set then an SCI
event is generated whenever the TMR_STS bit is set. When this bit is reset
then no interrupt is generated even when the TMR_STS bit is set.
1-4
5
Reserved
GBL_EN
Reserved. These bits always return a value of zero.
The global enable bit. When both the GBL_EN bit and the GBL_STS bit are
set, an SCI interrupt is raised.
6-7
Reserved
Reserved.
9.3.4 Power Management 1 Enable Register 2 (PM1EN2)
Register Location:
Default Value:
Attribute:
Size:
8 bits
7
6
<CR60, 61> + 3H System I/O Space
00h
Read/write
5
4
3
2
1
0
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Bit
0-7
Name
Reserved
Description
Reserved. These bits always return zeros.
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9.3.5 Power Management 1 Control Register 1 (PM1CTL1)
Register Location:
Default Value:
Attribute:
Size:
8 bits
7
6
<CR60, 61> + 4H System I/O Space
00h
Read/write
5
4
3
2
1
0
SCI_EN
BM_RLD
GBL_RLD
Reserved
Reserved
Reserved
Reserved
Reserved
Bit
0
Name
Description
SCI_EN
Select whether the power management event triggers an SCI or an SMI
interrupt. When this bit is set, then the power management events will
generate an SCI interrupt. When this bit is reset and SMI_EN bit is set, then
the power management events will generate an SMI interrupt.
This is the bus master reload enable bit. If this bit is set and BM_CNTRL is
set, an SCI interrupt is raised.
1
BM_RLD
2
GBL_RLS
The global release bit. This bit is used by the ACPI software to raise an event
to the BIOS software. The BIOS software has a corresponding enable and
status bit to control its ability to receive the ACPI event. Setting GBL_RLS
sets BIOS_STS, and it generates an SMI interrupt if BIOS_EN is also set.
3-7
Reserved
Reserved. These bits always return zeros.
9.3.6 Power Management 1 Control Register 2 (PM1CTL2)
Register Location:
Default Value:
Attribute:
Size:
8 bits
7
6
<CR60, 61> + 5H System I/O Space
00h
Read/write
5
4
3
2
1
0
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Bit
0-7
Name
Reserved
Description
Reserved. These bits always return zeros.
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9.3.7 Power Management 1 Control Register 3 (PM1CTL3)
Register Location:
<CR60, 61> + 6H System I/O Space
Default Value:
00h
Attribute:
Read/write
Size:
8 bits
7
6
5
4
3
2
1
0
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Bit
0-7
Name
Description
Reserved
Reserved. These bits always return zeros.
9.3.8 Power Management 1 Control Register 4 (PM1CTL4)
Register Location:
<CR60, 61> + 7H System I/O Space
Default Value:
00h
Attribute:
Read/write
Size:
8 bits
7
6
5
4
3
2
1
0
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Bit
0-7
Name
Reserved
Description
Reserved. These bits always return zeros.
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9.3.9 Power Management 1 Timer 1 (PM1TMR1)
Register Location:
<CR60, 61> + 8H System I/O Space
Default Value:
00h
Attribute:
Read only
Size:
8 bits
7
6
5
4
3
2
1
0
TMR_VAL0
TMR_VAL1
TMR_VAL2
TMR_VAL3
TMR_VAL4
TMR_VAL5
TMR_VAL6
TMR_VAL7
Bit
0-7
Name
Description
TMR_VAL
9.3.10
This read-only field returns the running count of the power management timer.
This is a 24-bit counter that runs off of a 3.579545 MHZ clock, and counts in
the working state. The timer is reset and then continues counting until the
CLKIN input the the chip is stopped. If the clock is restarted without a MR
reset, then the counter will resume counting from where it stopped. The
TMR_STS bit is set any time the last bit of the timer (bit 23) goes from 0 to 1
or from 1 to 0. If the TMR_EN bit is set, the setting of the TMR_STS bit will
generate an SCI interrupt.
Power Management 1 Timer 2 (PM1TMR2)
Register Location:
<CR60, 61> + 9H System I/O Space
Default Value:
00h
Attribute:
Read only
Size:
8 bits
7
6
5
4
3
2
1
0
TMR_VAL8
TMR_VAL9
TMR_VAL10
TMR_VAL11
TMR_VAL12
TMR_VAL13
TMR_VAL14
TMR_VAL15
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Bit
0-7
9.3.11
Name
Description
TMR_VAL
This read-only field returns the running count of the power management timer.
This is a 24-bit counter that runs off of a 3.579545 MHZ clock, and counts in
the working state. The timer is reset and then continues counting until the
CLKIN input the the chip is stopped. If the clock is restarted without a MR
reset, then the counter will resume counting from where it stopped. The
TMR_STS bit is set any time the last bit of the timer (bit 23) goes from 0 to 1
or from 1 to 0. If the TMR_EN bit is set, the setting of the TMR_STS bit will
generate an SCI interrupt.
Power Management 1 Timer 3 (PM1TMR3)
Register Location:
<CR60, 61> + AH System I/O Space
Default Value:
00h
Attribute:
Read only
Size:
8 bits
7
6
5
4
3
2
1
0
TMR_VAL16
TMR_VAL17
TMR_VAL18
TMR_VAL19
TMR_VAL20
TMR_VAL21
TMR_VAL22
TMR_VAL23
Bit
0-7
Name
TMR_VAL
Description
This read-only field returns the running count of the power management timer.
This is a 24-bit counter that runs off of a 3.579545 MHZ clock, and counts in
the working state. The timer is reset and then continues counting until the
CLKIN input the the chip is stopped. If the clock is restarted without a MR
reset, then the counter will resume counting from where it stopped. The
TMR_STS bit is set any time the last bit of the timer (bit 23) goes from 0 to 1
or from 1 to 0. If the TMR_EN bit is set, the setting of the TMR_STS bit will
generate an SCI interrupt.
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9.3.12
Power Management 1 Timer 4 (PM1TMR4)
Register Location:
<CR60, 61> + BH System I/O Space
Default Value:
00h
Attribute:
Read only
Size:
8 bits
7
6
5
4
2
3
1
0
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Bit
0-7
9.3.13
Name
Reserved
Description
Reserved. These bits always return zeros.
General Purpose Event 0 Status Register 1 (GP0STS1)
Register Location:
<CR62, 63> System I/O Space
Default Value:
00h
Attribute:
Read/write
Size:
8 bits
7
6
5
4
3
2
1
0
URBSCISTS
URASCISTS
FDCSCISTS
PRTSCISTS
KBCSCISTS
MOUSCISTS
Reserved
Reserved
These bits indicate the status of the SCI input, which is set when the device's IRQ is raised. If the
corresponding enable bit in the SCI interrupt enable register (in GP0EN1) is set, an SCI interrupt is
raised and routed to the output pin. Wrinting a 1 clears the bit, and wrinting a 0 has no effect. If the
bit is not cleared, new IRQ to the SCI logic input is ignored and no SCI interrupt will be raised.
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Bit
Name
Description
0
URBSCISTS
UART B SCI status, which is set by the UART B IRQ.
1
URASCISTS
UART A SCI status, which is set by the UART A IRQ.
2
FDCSCISTS
FDC SCI status, which is set by the FDC IRQ.
3
PRTSCISTS
PRT SCI status, which is set by the printer port IRQ.
4
KBCSCISTS
KBC SCI status, which is set by the KBC IRQ.
5
MOUSCISTS
MOUSE SCI status, which is set by the MOUSE IRQ.
6-7
Reserved
Reserved.
9.3.14
General Purpose Event 0 Status Register 2 (GP0STS2)
Register Location:
<CR62, 63> + 1H System I/O Space
Default Value:
00h
Attribute:
Read/write
Size:
8 bits
7
6
5
4
3
2
1
0
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Bit
0-7
Name
Reserved
Description
Reserved. These bits always return zeros.
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9.3.15 General Purpose Event 0 Enable Register 1 (GP0EN1)
Register Location:
<CR62, 63> + 2H System I/O Space
Default Value:
00h
Attribute:
Read/write
Size:
8 bits
7
6
5
4
3
2
1
0
URBSCIEN
URASCIEN
FDCSCIEN
PRTSCIEN
KBCSCIEN
MOUSCIEN
Reserved
Reserved
These bits are used to enable the device's IRQ sources into the SCI logic. The SCI logic output for
the IRQs is as follows:
SCI logic output = (URBSCIEN and URBSCISTS) or (URASCIEN and URASCISTS) or (FDCSCIEN
and FDCSCISTS) or (PRTSCIEN and PRTSCISTS) or (KBCSCIEN and KBCSCISTS) or
(MOUSCIEN and MOUSCISTS)
Bit
0
Name
URBSCIEN
Description
UART B SCI enable, which controls the UART B IRQ.
1
URASCIEN
UART A SCI enable, which controls the UART A IRQ.
2
FDCSCIEN
FDC SCI enable, which controls the FDC IRQ.
3
PRTSCIEN
printer port SCI enable, which controls the printer port IRQ.
4
KBCSCIEN
KBC SCI enable, which controls the KBC IRQ.
5
MOUSCIEN
6-7
Reserved
MOUSE SCI enable, which controls the MOUSE IRQ.
Reserved.
9.3.16 General Purpose Event 0 Enable Register 2 (GP0EN2)
Register Location:
<CR62, 63> + 3H System I/O Space
Default Value:
00h
Attribute:
Read/write
Size:
8 bits
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7
6
5
4
2
3
1
0
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Bit
0-7
9.3.17
Name
Description
Reserved
Reserved. These bits always return zeros.
General Purpose Event 1 Status Register 1 (GP1STS1)
Register Location:
<CR64, 65> System I/O Space
Default Value:
00h
Attribute:
Read/write
Size:
8 bits
7
6
5
4
3
2
1
0
BIOS_STS
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Bit
Name
0
BIOS_STS
1-7
Reserved
9.3.18
Description
The BIOS status bit. This bit is set when GBL_RLS is set. If BIOS_EN is set,
setting GBL_RLS will raise an SMI event. Writing a 1 to its bit location clears
BIOS_STS and also clears GBL_RLS. Writing a 0 has no effect.
Reserved.
General Purpose Event 1 Status Register 2 (GP1STS2)
Register Location:
<CR64, 65> + 1H System I/O Space
Default Value:
Attribute:
Size:
8 bits
00h
Read/write
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7
6
5
4
2
3
1
0
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Bit
0-7
Name
Reserved
Description
Reserved. These bits always return zeros.
9.3.19 General Purpose Event 1 Enable Register 1 (GP1EN1)
Register Location:
<CR64, 65> + 2H System I/O Space
Default Value:
00h
Attribute:
Read/write
Size:
8 bits
7
6
5
4
3
2
1
0
BIOS_EN
TMR_ON
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Bit
0
Name
BIOS_EN
1
TMR_ON
2-7
Reserved
Description
This bit is raise the SMI event. When this bit is set and the ACPI software
writes a 1 to the GBL_RLS bit, an SMI event is raised on the SMI logic
output.
This bit is used to turn on the power management timer.
1 = timer on; 0 = timer off.
Reserved.
9.3.20 General Purpose Event 1 Enable Register 2 (GP1EN2)
Register Location:
<CR64, 65> + 3H System I/O Space
Default Value:
00h
Attribute:
Read/write
Size:
8 bits
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7
6
5
4
3
2
1
0
BIOS_RLS
BM_CNTRL
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Bit
Name
0
BIOS_RLS
1
BM_CNTRL
2-7
Reserved
9.3.21
Description
The BIOS release bit. This bit is used by the BIOS software to raise an event
to the ACPI software. The ACPI software has a corresponding enable and
status bit to control its ability to receive the ACPI event. Setting BIOS_RLS
sets GBL_STS, and it generates an SCI interrupt if GBL_EN is also set.
Writing a 1 to its bit position sets this bit and also sets the BM_STS bit.
Writing a 0 has no effect. This bit is cleared by writing a 1 to the GBL_STS
bit.
This bit is used to set the BM_STS bit and if the BM_RLD bit is also set, then
an SCI interrupt is generated. Writing a 1 sets BM_CNTRL to 1 and also sets
BM_STS. Writing a 0 has no effect. Wrinting a 1 to BM_STS clears
BM_STS and also clears BM_CNTRL.
Reserved.
Bit Map Configuration Registers
Table 9-1: Bit Map of PM1 Register Block
Register
PM1STS1
PM1STS2
PM1EN1
PM1EN2
PM1CTL1
PM1CTL2
PM1CTL3
PM1CTL4
PM1TMR1
PM1TMR2
PM1TMR3
PM1TMR4
Address
<CR60,61>
<CR60,61>
+1H
<CR60,61>
+2H
<CR60,61>
+3H
<CR60,61>
+4H
<CR60,61>
+5H
<CR60,61>
+6H
<CR60,61>
+7H
<CR60,61>
+8H
<CR60,61>
+9H
<CR60,61>
+AH
<CR60,61>
+BH
Power-On
Reset
Value
D7
D6
D5
D4
D3
D2
D1
0000 0000
0000 0000
0
WAK_STS
0
0
GBL_STS
0
BM_STS
0
0
0
0
0
0
0
TMR_STS
0
0000 0000
0
0
GBL_EN
0
0
0
0
TMR_EN
0000 0000
0
0
0
0
0
0
0
0
0000 0000
0
0
0
0
0
GBL_RLS
BM_RLD
SCI_EN
0000 0000
0
0
0
0
0
0
0
0
0000 0000
0
0
0
0
0
0
0
0
0000 0000
0
0
0
0
0
0
0
0
0000 0000
TMR_VAL7
TMR_VAL6
TMR_VAL5
TMR_VAL4
TMR_VAL3
TMR_VAL2
TMR_VAL1
TMR_VAL0
0000 0000
TMR_VAL15
TMR_VAL14
TMR_VAL13
TMR_VAL12
TMR_VAL11
TMR_VAL10
TMR_VAL9
TMR_VAL8
0000 0000
TMR_VAL23
TMR_VAL22
TMR_VAL21
TMR_VAL20
TMR_VAL19
TMR_VAL18
TMR_VAL17
TMR_VAL16
0000 0000
0
0
0
0
0
0
0
-92 -
D0
Publication Release Date:March 1998
Revision 0.62
W83977TF
PRELIMINARY
Table 9-2: Bit Map of GPE Register Block
Register
Address
Power-On
D7
D6
D5
D4
D3
D2
D1
D0
Reset Value
GP0STS1
<CR62,63>
0000 0000
0
0
MOUSCISTS
KBCSCISTS
PRTSCISTS
FDCSCISTS
URASCISTS
URBSCISTS
GP0STS2
<CR62,63>
+1H
0000 0000
0
0
0
0
0
0
0
0
GP0EN1
<CR62,63>
+2H
0000 0000
0
0
MOUSCIEN
KBCSCIEN
PRTSCIEN
FDCSCIEN
URASCIEN
URBSCIEN
GP0EN2
<CR62,63>
+3H
0000 0000
0
0
0
0
0
0
0
0
GP1STS1
<CR64,65>
0000 0000
0
0
0
0
0
0
0
BIOS_STS
GP1STS2
<CR64,65>
+1H
0000 0000
0
0
0
0
0
0
0
0
GP1EN1
<CR64,65>
+2H
0000 0000
0
0
0
0
0
0
TMR_ON
BIOS_EN
GP1EN2
<CR64,65>
+3H
0000 0000
0
0
0
0
0
0
BM_CNTRL
BIOS_RLS
10. SERIAL IRQ
W83977TF supports a serial IRQ scheme. This allow a signal line to be used to report the legacy ISA
interrupt rerquests. Because more than one device may need to share the signal serial IRQ signal
line, an open drain signal scheme is used. The clock source is the PCI clock. The serial interrupt is
transfered on the IRQSER signal, one cycle consisting of three frames types: a start frame, several
IRQ/Data frame, and one Stop frame. The serial interrupt scheme adheres to the Serial IRQ
Specification for PCI System, Version 6.0.
Timing Diagrams For IRQSER Cycle
Start Frame timing with source sampled a low pulse on IRQ1
SL
or
H
START FRAME
H
IRQ0 FRAME
R
T
S
R
T
IRQ1 FRAME
S
R
IRQ2 FRAME
T
S
R
T
PCICLK
IRQSER
Drive Source
H=Host Control
1
START
IRQ1
Host Controller
SL=Slave Control
None
R=Recovery
IRQ1
T=Turn-around
None
S=Sample
1. Start Frame pulse can be 4-8 clocks wide.
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Publication Release Date:March 1998
Revision 0.62
W83977TF
PRELIMINARY
Stop Frame Timing with Host using 17 IRQSER sampling period
IRQ14
FRAME
S
R
IRQ15
FRAME
T
S
R
IOCHCK
FRAME
T
S
R
STOP FRAME
T
2
I
H
NEXT CYCLE
R
T
PCICLK
1
STOP
IRQSER
Drive
None
H=Host Control
IRQ15
R=Recovery
None
3
START
Host Controller
T=Turn-around
S=Sample
I=Idle
1. Stop pulse is 2 clocks wide for Quiet mode, 3 clocks wide for Continuous mode.
2. There may be none, one or more Idle states during the Stop Frame.
3. The next IRQSER cycle's Start Frame pulse may or may not start immediately after the turn-around clock of the Stip Frame.
10.1 Start Frame
There are two modes of operation for the IRQSER Start frame: Quiet mode and Continuous mode.
In the Quiet mode, the peripheral drives the SERIRQ signal active low for one clock, and then tristates it. This brings all the states machines of the peripherals from idle to active states. The host
controller will then take over driving IRQSER signal low in the next clock and will continue driving the
IRQSER low for programmable 3 to 7 clock periods. This makes the total number of clocks low for 4
to 8 clock periods. After these clocks, the host controller will drive the IRQSER high for one clock
and then tri-states it.
In the Continuous mode, only the host controller initiates the START frame to update IRQ/Data line
information. The host controller drives the IRQSER signal low for 4 to 8 clock periods. Upon a reset,
the IRQSER signal is defaulted to the Continuous mode for the host controller to initiate the first Start
frame.
10.2 IRQ/Data Frame
Once the start frame has been initiated, all the peripherals must start counting frames based on the
rsing edge of the start pulse. Each IRQ/Data Frame is three clocks: Sample phase, Recovery phase,
and Turn-around phase.
During the Sample phase, the peripheral drives SERIRQ low if the corresponding IRQ is active. If the
corresponding IRQ is inactive, then IRQSER must be left tri-stated. During the Recovery phase, the
peripheral device drives the IRQSER high. During the Turn-around phase, the peripheral device left
the IRQSER tri-stated.
The IRQ/Data Frame has a number of specific order, as shown in Table 10-1.
10.3 Stop Frame
After all IRQ/Data Frames have completed, the host controller will terminate IRQSER by a Stop
frame. Only the host controller can initiate the Stop frame by driving IRQSER low for 2 or 3 clocks. If
the Stop Frame is low for 2 clocks, the next IRQSER cycle's Sample mode is the Quiet mode. If the
Stop Frame is low for 3 clocks, the next IRQSER cycle's Sample mode is the Continuous mode.
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Publication Release Date:March 1998
Revision 0.62
W83977TF
PRELIMINARY
Table 10-1 IRQSER Sampling periods
IRQ/Data Frame
Signal Sampled
# of clocks past Start
1
IRQ0
2
2
IRQ1
5
3
SMI
8
4
IRQ3
11
5
IRQ4
14
6
IRQ5
17
7
IRQ6
20
8
IRQ7
23
9
IRQ8
26
10
IRQ9
29
11
IRQ10
32
12
IRQ11
35
13
IRQ12
38
14
IRQ13
41
15
IRQ14
44
16
IRQ15
47
17
IOCHCK
50
18
INTA
53
19
INTB
56
20
INTC
59
21
INTD
62
32:22
Unassigned
95
10.4 Reset and Initialization
After MR reset, IRQSER Slaves are put into the Continuous(Idle) mode. The Host Controller is
responsible for starting the initial IRQSER Cycle to collect system's IRQ/Data default values. The
system then follows with the Continuous/Quiet mode protocol (Stop Frame pulse width) for
subsequent IRQSER cycles. It's the Host Controller's responsibility to provide the default values to
8259's and other system logic before the first IRQSER cycle is performed. For IRQSER system
suspend, insertion, or removal application, the Host controller should be programmed into
Continuous(Idle) mode first. This is to guarantee IRQSER bus in the Idle state before the system
configuration changes.
-95 -
Publication Release Date:March 1998
Revision 0.62
W83977TF
PRELIMINARY
11. CONFIGURATION REGISTER
11.1 Chip (Global) Control Register
CR02 (Default 0x00)
Bit 7 - 1: Reserved.
Bit 0: SWRST --> Soft Reset.
CR07
Bit 7 - 0: LDNB7 - LDNB0 --> Logical Device Number Bit 7 - 0
CR20
Bit 7 - 0: DEVIDB7 - DEBIDB0 --> Device ID Bit 7 - Bit 0 = 0x97 (read only).
CR21
Bit 7 - 0: DEVREVB7 - DEBREVB0 --> Device Rev Bit 7 - Bit 0 = 0x73 (read only).
CR22 (Default 0xff)
Bit 7 - 6: Reserved.
Bit 5: URBPWD
= 0 Power down
= 1 No Power down
Bit 4: URAPWD
= 0 Power down
= 1 No Power down
Bit 3: PRTPWD
= 0 Power down
= 1 No Power down
Bit 2, 1: Reserved.
Bit 0: FDCPWD
= 0 Power down
= 1 No Power down
CR23 (Default 0xFE)
Bit 7 - 1: Reserved.
Bit 0: IPD (Immediate Power Down). When set to 1, it will put the whole chip into power down
mode immediately.
CR24 (Default 0b1s000s0s)
Bit 7: EN16SA
= 0 12 bit Address Qualification
= 1 16 bit Address Qualification
Bit 6: EN48
= 0 The clock input on Pin 1 should be 24 Mhz.
= 1 The clock input on Pin 1 should be 48 Mhz.
The corresponding power-on setting pin is SOUTB (pin 53).
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Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
Bit 5 - 3: Reserved.
Bit 2: ENKBC
= 0 KBC is disabled after hardware reset.
= 1 KBC is enabled after hardware reset.
This bit is read only, and set/reset by power-on setting pin. The corresponding power-on
setting pin is SOUTA (pin 46).
Bit 1: Reserved
Bit 0: PNPCSV
= 0 The Compatible PnP address select registers have default values.
= 1 The Compatible PnP address select registers have no default value.
When trying to make a change to this bit, new value of PNPCSV must be complementary
to the old one to make an effective change. For example, the user must set PNPCSV to 0
first and then reset it to 1 to reset these PnP registers if the present value of PNPCSV is 1.
The corresponding power-on setting pin is NDTRA (pin 44).
CR25 (Default 0x00)
Bit 7 - 6: Reserved
Bit 5: URBTRI
Bit 4: URATRI
Bit 3: PRTTRI
Bit 2 - 1 : Reserved
Bit 0: FDCTRI.
CR26 (Default 0b0s000000)
Bit 7: SEL4FDD
= 0 Select two FDD mode.
= 1 Select four FDD mode.
Bit 6: HEFRAS
These two bits define how to enable Configuration mode. The corresponding power-on
setting pin is NRTSA (pin 43).
HEFRAS Address and Value
= 0 Write 87h to the location 3F0h twice.
= 1 Write 87h to the location 370h twice.
Bit 5: LOCKREG
= 0 Enable R/W Configuration Registers.
= 1 Disable R/W Configuration Registers.
Bit 4: Reserved.
Bit 3: DSFDLGRQ
= 0 Enable FDC legacy mode on IRQ and DRQ selection, then DO register bit 3 is effective
on selecting IRQ
= 1 Disable FDC legacy mode on IRQ and DRQ selection, then DO register bit 3 is not
effective on selecting IRQ
-97 -
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
Bit 2: DSPRLGRQ
= 0 Enable PRT legacy mode on IRQ and DRQ selection, then DCR bit 4 is effective on
selecting IRQ
= 1 Disable PRT legacy mode on IRQ and DRQ selection, then DCR bit 4 is not effective
on selecting IRQ
Bit 1: DSUALGRQ
= 0 Enable UART A legacy mode IRQ selecting, then MCR bit 3 is effective on selecting
IRQ
= 1 Disable UART A legacy mode IRQ selecting, then MCR bit 3 is not effective on
selecting IRQ
Bit 0: DSUBLGRQ
= 0 Enable UART B legacy mode IRQ selecting, then MCR bit 3 is effective on selecting
IRQ
= 1 Disable UART B legacy mode IRQ selecting, then MCR bit 3 is not effective on
selecting IRQ
CR28 (Default 0x00)
Bit 7 - 5: Reserved.
Bit 4: IRQ Sharing selection.
=0
Disable IRQ Sharing
=1
Enable IRQ Sharing
Bit 3:Reserved
Bit 2 - 0: PRTMODS2 - PRTMODS0
= 0xx Parallel Port Mode
= 100 Reserved
= 101 External FDC Mode
= 110 Reserved
= 111 External two FDC Mode
CR2A (Default 0x00)
Bit 7: PIN57S
= 0 KBRST
= 1 GP12
Bit 6: PIN56S
= 0 GA20
= 1 GP11
Bit 5 - 4: PIN40S1, PIN40S0
= 00 Reserved
= 01 GP24
= 10 8042 P13
= 11 Reserved
Bit 3 - 2: Reserved.
Bit 1 - 0: PIN3S1, PIN3S0
= 00 DRVDEN1
= 01 GP10
= 10 8042 P12
= 11 SCI
-98 -
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
CR2B (Default 0x00)
Bit 7 - 6: PIN73S1, PIN73S0
= 00 PANSWIN
= 01 GP23
= 10 Reserved
= 11 Reserved
Bit 5: PIN72S
PANSWOUT
=0
= 1 GP22
Bit 4 - 3: PIN70S1, PIN70S0
= 00 SMI
= 01 GP21
= 10 8042 P16
= 11 Reserved
Bit 2 - 1: Reserved.
Bit 0: PIN58S
= 0 KBLOCK
= 1 GP13
CR2C (Default 0x00)
Bit 7 - 6: PIN121S1, PIN121S0
= 00 DRQ0
= 01 GP17
= 10 8042 P14
= 11 SCI
Bit 5 - 4: PIN119S1, PIN119S0
= 00 NDACK0
= 01 GP16
= 10 8042 P15
= 11 Reserved
Bit 3 - 2: PIN104S1, PIN104S0
= 00 IRQ15
= 01 GP15
= 10 WDTO
= 11 Reserved
Bit 1 - 0: PIN103S1, PIN103S0
= 00 IRQ14
= 01 GP14
= 10 PLEDO
= 11 Reserved
CR2D (Default 0x00)
Test Modes: Reserved for Winbond.
CR2E (Default 0x00)
Test Modes: Reserved for Winbond.
CR2F (Default 0x00)
Test Modes: Reserved for Winbond.
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Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
11.2 Logical Device 0 (FDC)
CR30 (Default 0x01 if PNPCSV = 0 during POR, default 0x00 otherwise)
Bit 7 - 1: Reserved.
Bit 0: = 1 Activates the logical device.
= 0 Logical device is inactive.
CR60, CR 61 (Default 0x03, 0xf0 if PNPCSV = 0 during POR, default 0x00, 0x00 otherwise)
These two registers select FDC I/O base address [0x100:0xFF8] on 8 byte boundary.
CR70 (Default 0x06 if PNPCSV = 0 during POR, default 0x00 otherwise)
Bit 7 - 4: Reserved.
Bit 3 - 0: These bits select IRQ resource for FDC.
CR74 (Default 0x02 if PNPCSV = 0 during POR, default 0x04 otherwise)
Bit 7 - 3: Reserved.
Bit 2 - 0: These bits select DRQ resource for FDC.
= 0x00 DMA0
= 0x01 DMA1
= 0x02 DMA2
= 0x03 DMA3
= 0x04 - 0x07 No DMA active
CRF0 (Default 0x0E)
FDD Mode Register
Bit 7: FIPURDWN
This bit controls the internal pull-up resistors of the FDC input pins RDATA, INDEX, TRAK0,
DSKCHG, and WP.
= 0 The internal pull-up resistors of FDC are turned on.(Default)
= 1 The internal pull-up resistors of FDC are turned off.
Bit 6: INTVERTZ
This bit determines the polarity of all FDD interface signals.
= 0 FDD interface signals are active low.
= 1 FDD interface signals are active high.
Bit 5: DRV2EN (PS2 mode only)
When this bit is a logic 0, this indicates that a second drive is installed and is reflected in status
register A.
Bit 4: Swap Drive 0, 1 Mode
= 0 No Swap (Default)
= 1 Drive and Motor sel 0 and 1 are swapped.
Bit 3 - 2 Interface Mode
= 11 AT Mode (Default)
= 10 (Reserved)
= 01 PS/2
= 00 Model 30
Bit 1: FDC DMA Mode
= 0 Burst Mode is enabled
= 1 Non-Burst Mode (Default)
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Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
Bit 0: Floppy Mode
= 0 Normal Floppy Mode (Default)
= 1 Enhanced 3-mode FDD
CRF1 (Default 0x00)
Bit 7 - 6: Boot Floppy
= 00 FDD A
= 01 FDD B
= 10 FDD C
= 11 FDD D
Bit 5, 4: Media ID1, Media ID0. These bits will be reflected on FDC's Tape Drive Register bit 7, 6.
Bit 3 - 2: Density Select
= 00 Normal (Default)
= 01 Normal
= 10 1 ( Forced to logic 1)
= 11 0 ( Forced to logic 0)
Bit 1: DISFDDWR
= 0 Enable FDD write.
= 1 Disable FDD write(forces pins WE, WD stay high).
Bit 0: SWWP
= 0 Normal, use WP to determine whether the FDD is write protected or not.
= 1 FDD is always write-protected.
CRF2 (Default 0xFF)
Bit 7 - 6: FDD D Drive Type
Bit 5 - 4: FDD C Drive Type
Bit 3 - 2: FDD B Drive Type
Bit 1:0: FDD A Drive Type
When FDD is in enhanced 3-mode(CRF0.bit0=1),these bits determine SELDEN value in TABLE A
of CRF4 and CRF5 as follows.
DTYPE1
DPYTE0
DRATE1
DRATE0
SELDEN
0
0
1
1
1
0
0
0
0
1
0
0
0
1
0
0
0
1
0
0
0
1
X
X
0
1
0
X
X
1
1
1
0
1
0
Note: X means don't care.
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Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
CRF4 (Default 0x00)
FDD0 Selection:
Bit 7: Reserved.
Bit 6: Precomp. Disable.
= 1 Disable FDC Precompensation.
= 0 Enable FDC Precompensation.
Bit 5: Reserved.
Bit 4 - 3: DRTS1, DRTS0: Data Rate Table select (Refer to TABLE A).
= 00 Select Regular drives and 2.88 format
= 01 Specifical application
= 10 2 Meg Tape
= 11 Reserved
Bit 2: Reserved.
Bit 1:0: DMOD0, DMOD1 : Drive Model select (Refer to TABLE B).
CRF5 (Default 0x00)
FDD1 Selection: Same as FDD0 of CRF4.
-101.1 -
Publication Release Date: July 1997
Revision 0.61
W83977TF
PRELIMINARY
TABLE A
Drive Rate Table
Select
Data Rate
Selected Data Rate
SELDEN
DRTS1
DRTS0
DRATE1
DRATE0
MFM
FM
CRF0 bit 0=0
0
0
1
0
1
0
1Meg
500K
--250K
1
1
0
1
1
1
0
1
300K
250K
1Meg
150K
125K
---
0
0
1
0
1
0
0
1
1
0
1
0
1
500K
500K
250K
1Meg
250K
250K
125K
---
1
0
0
1
1
0
0
0
1
0
1
0
500K
2Meg
250K
250K
--125K
1
0
0
Note:Refer to CRF2 for SELDEN value in the cases when CRF0, bit0=1.
TABLE B
DMOD0
DMOD1
DRVDEN0(pin 2)
DRVDEN1(pin 3)
0
0
SELDEN
DRATE0
0
1
1
0
DRATE1
DRATE0
DRATE0
1
1
SELDEN
DRATE0
DRIVE TYPE
4/2/1 MB 3.5” “
2/1 MB 5.25”
2/1.6/1 MB 3.5” (3-MODE)
DRATE1
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Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
11.3 Logical Device 1 (Parallel Port)
CR30 (Default 0x01 if PNPCSV = 0 during POR, default 0x00 otherwise)
Bit 7 - 1: Reserved.
Bit 0:
= 1 Activates the logical device.
= 0 Logical device is inactive.
CR60, CR 61 (Default 0x03, 0x78 if PNPCSV = 0 during POR, default 0x00, 0x00 otherwise)
These two registers select Parallel Port I/O base address.
[0x100:0xFFC] on 4 byte boundary (EPP not supported) or
[0x100:0xFF8] on 8 byte boundary (all modes supported, EPP is only available when the base
address is on 8 byte boundary).
CR70 (Default 0x07 if PNPCSV = 0 during POR, default 0x00 otherwise)
Bit 7 - 4: Reserved.
Bit [3:0]: These bits select IRQ resource for Parallel Port.
CR74 (Default 0x04)
Bit 7 - 3: Reserved.
Bit 2 - 0: These bits select DRQ resource for Parallel Port.
0x00=DMA0
0x01=DMA1
0x02=DMA2
0x03=DMA3
0x04 - 0x07= No DMA active
CRF0 (Default 0x3F)
Bit 7: PP Interrupt Type:
Not valid when the parallel port is in the printer Mode (100) or the standard & Bi-directional
Mode (000).
= 1 Pulsed Low, released to high-Z .
= 0 IRQ follows nACK when parallel port in EPP Mode or [Printer, SPP, EPP] under ECP.
Bit [6:3]: ECP FIFO Threshold.
Bit 2 - 0 Parallel Port Mode
= 100 Printer Mode (Default)
= 000 Standard and Bi-direction (SPP) mode
= 001 EPP - 1.9 and SPP mode
= 101 EPP - 1.7 and SPP mode
= 010 ECP mode
= 011 ECP and EPP - 1.9 mode
= 111 ECP and EPP - 1.7 mode.
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Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
11.4
Logical Device 2 (UART A)¢)
CR30 (Default 0x01 if PNPCSV = 0 during POR, default 0x00 otherwise)
Bit 7 - 1: Reserved.
Bit 0:
= 1 Activates the logical device.
= 0 Logical device is inactive.
CR60, CR 61 (Default 0x03, 0xF8 if PNPCSV = 0 during POR, default 0x00, 0x00 otherwise)
These two registers select Serial Port 1 I/O base address [0x100:0xFF8] on 8 byte boundary.
CR70 (Default 0x04 if PNPCSV = 0 during POR, default 0x00 otherwise)
Bit 7 - 4: Reserved.
Bit 3 - 0: These bits select IRQ resource for Serial Port 1.
CRF0 (Default 0x00)
Bit 7 - 2: Reserved.
Bit 1 - 0: SUACLKB1, SUACLKB0
= 00
UART A clock source is 1.8462 Mhz (24MHz/13)
= 01
UART A clock source is 2 Mhz (24MHz/12)
= 10
UART A clock source is 24 Mhz (24MHz/1)
= 11
UART A clock source is 14.769 Mhz (24MHz/1.625)
11.5 Logical Device 3 (UART B)
CR30 (Default 0x01 if PNPCSV = 0 during POR, default 0x00 otherwise)
Bit 7 - 1: Reserved.
Bit 0:
= 1 Activates the logical device.
= 0 Logical device is inactive.
CR60, CR 61 (Default 0x02, 0xF8 if PNPCSV = 0 during POR, default 0x00, 0x00 otherwise)
These two registers select Serial Port 2 I/O base address [0x100:0xFF8] on 8 byte boundary.
CR70 (Default 0x03 if PNPCSV = 0 during POR, default 0x00 otherwise)
Bit 7 - 4: Reserved.
Bit [3:0]: These bits select IRQ resource for Serial Port 2.
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Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
CRF0 (Default 0x00)
Bit 7 - 4: Reserved.
Bit 3: RXW4C
=0
No reception delay when SIR is changed from TX mode to RX mode.
=1
Reception delays 4 characters-time (40 bit-time) when SIR is changed from TX mode
to RX mode.
Bit 2: TXW4C
=0
No transmission delay when SIR is changed from RX mode to TX mode.
=1
Transmission delays 4 characters-time (40 bit-time) when SIR is changed from RX
mode to TX mode.
Bit 1 - 0: SUBCLKB1, SUBCLKB0
= 00
UART B clock source is 1.8462 Mhz (24MHz/13)
= 01
UART B clock source is 2 Mhz (24MHz/12)
= 10
UART B clock source is 24 Mhz (24MHz/1)
= 11
UART B clock source is 14.769 Mhz (24MHz/1.625)
CRF1 (Default 0x00)
Bit 7: Reserved.
Bit 6: IRLOCSEL. IR I/O pins' location select.
=0
Through SINB/SOUTB.
=1
Through IRRX/IRTX.
Bit 5: IRMODE2. IR function mode selection bit 2.
Bit 4: IRMODE1. IR function mode selection bit 1.
Bit 3: IRMODE0. IR function mode selection bit 0.
IR MODE
IR FUNCTION
IRTX
IRRX
00X
Disable
tri-state
high
010*
IrDA
Active pulse 1.6 µS
Demodulation into SINB/IRRX
011*
IrDA
Active pulse 3/16 bit time
Demodulation into SINB/IRRX
100
ASK-IR
Inverting IRTX/SOUTB pin
routed to SINB/IRRX
101
ASK-IR
Inverting IRTX/SOUTB & 500
KHZ clock
routed to SINB/IRRX
110
ASK-IR
Inverting IRTX/SOUTB
Demodulation into SINB/IRRX
111*
ASK-IR
Inverting IRTX/SOUTB & 500
KHZ clock
Demodulation into SINB/IRRX
Note: The notation is normal mode in the IR function.
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Revision 0.62
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Bit 2: HDUPLX. IR half/full duplex function select.
=0
The IR function is Full Duplex.
=1
The IR function is Half Duplex.
Bit 1: TX2INV.
=0
the SOUTB pin of UART B function or IRTX pin of IR function in normal condition.
=1
inverse the SOUTB pin of UART B function or IRTX pin of IR function.
Bit 0: RX2INV.
=0
the SINB pin of UART B function or IRRX pin of IR function in normal condition.
=1
inverse the SINB pin of UART B function or IRRX pin of IR function
11.6 Logical Device 5 (KBC)
CR30 (Default 0x01 if PENKBC= 1 during POR, default 0x00 otherwise)
Bit 7 - 1: Reserved.
Bit 0:
= 1 Activates the logical device.
= 0 Logical device is inactive.
CR60, CR 61 (Default 0x00, 0x60 if PENKBC= 1 during POR, default 0x00 otherwise)
These two registers select the first KBC I/O base address [0x100:0xFFF] on 1 byte boundary.
CR62, CR 63 (Default 0x00, 0x64 if PENKBC= 1 during POR, default 0x00 otherwise)
These two registers select the second KBC I/O base address [0x100:0xFFF] on 1 byte boundary.
CR70 (Default 0x01 if PENKBC= 1 during POR, default 0x00 otherwise)
Bit 7 - 4: Reserved.
Bit [3:0]: These bits select IRQ resource for KINT (keyboard).
CR72 (Default 0x0C if PENKBC= 1 during POR, default 0x00 otherwise)
Bit 7 - 4: Reserved.
Bit [3:0]: These bits select IRQ resource for MINT (PS2 Mouse)
CRF0 (Default 0x83)
Bit 7 - 6: KBC clock rate selection
= 00 Select 6MHz as KBC clock input.
= 01 Select 8MHz as KBC clock input.
= 10 Select 12Mhz as KBC clock input.
= 11 Select 16Mhz as KBC clock input.
Bit 5 - 3: Reserved.
Bit 2: = 0 Port 92 disable.
= 1 Port 92 enable.
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Bit 1: = 0 Gate20 software control.
= 1 Gate20 hardware speed up.
Bit 0: = 0 KBRST software control.
= 1 KBRST hardware speed up.
11.7 Logical Device 7 (GP I/O Port I)
CR30 (Default 0x00)
Bit 7 - 1: Reserved.
Bit 0: = 1 Activates the logical device.
= 0 Logical device is inactive.
CR60, CR 61 (Default 0x00, 0x00)
These two registers select GP1 I/O base address [0x100:0xFFF] on 1 byte boundary.
CR62, CR 63 (Default 0x00, 0x00)
These two registers select GP14 alternate function Primary I/O base address [0x100:0xFFE] on 2
byte boundary; They are available as you setting GP14 to be an alternate function (General
Purpose Address Decode).
CR64, CR 65 (Default 0x00, 0x00)
These two registers select GP15 alternate function Primary I/O base address [0x100:0xFFF] on 1
byte boundary; They are available as you setting GP15 to be an alternate function (General
Purpose Write Decode).
CR70 (Default 0x00)
Bit 7 - 4: Reserved.
Bit 3 - 0: These bits select IRQ resource for GP10 as you setting GP10 to be an alternate function
(Interrupt Steering).
CR72 (Default 0x00)
Bit 7 - 4: Reserved.
Bit 3 - 0: These bits select IRQ resource for GP11 as you setting GP11 to be an alternate function
(Interrupt Steering).
CRE0 (GP10, Default 0x01)
Bit 7 - 5: Reserved.
Bit 4: IRQ Filter Select
= 1 Debounce Filter Enabled
= 0 Debounce Filter Bypassed
Bit 3: Select Function.
= 1 Select Alternate Function: Interrupt Steering.
= 0 Select Basic I/O Function.
Bit 2: Reserved.
Bit 1: Polarity.
= 1 Invert.
= 0 No Invert.
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Bit 0: In/Out selection.
= 1 Input.
= 0 Output.
CRE1 (GP11, Default 0x01)
Bit 7 - 5: Reserved.
Bit 4: IRQ Filter Select
= 1 Debounce Filter Enabled
= 0 Debounce Filter Bypassed
Bit 3: Select Function.
= 1 Select Alternate Function: Interrupt Steering.
= 0 Select Basic I/O Function.
Bit 2: Reserved.
Bit 1: Polarity.
= 1 Invert.
= 0 No Invert.
Bit 0: In/Out selection.
= 1 Input.
= 0 Output.
CRE2 (GP12, Default 0x01)
Bit 7 - 5: Reserved.
Bit 4 - 3: Select Function.
= 00 Select Basic I/O function.
= 01 Select 1st alternate function: Watch Dog Timer Output.
= 10 Reserved
= 11 Reserved
Bit 2: Reserved.
Bit 1: Polarity: 1: Invert, 0: No Invert
Bit 0: In/Out: 1: Input, 0: Output
CRE3 (GP13, Default 0x01)
Bit 7 - 5: Reserved.
Bit 4 - 3: Select Function.
= 00 Select Basic I/O function.
= 01 Select 1st alternate function: Power LED output.
= 10 Reserved
= 11 Reserved
Bit 2: Reserved.
Bit 1: Polarity: 1: Invert, 0: No Invert
Bit 0: In/Out: 1: Input, 0: Output
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CRE4 (GP14, Default 0x01)
Bit 7 - 5: Reserved.
Bit 4 - 3: Select Function.
= 00 Select Basic I/O function.
= 01 Select 1st alternate function: General Purpose Address Decoder(Active Low when
Bit 1 = 0, Decode two byte address).
= 10 Select 2nd alternate function: Keyboard Inhibit(P17).
= 11 Reserved
Bit 2: Reserved.
Bit 1: Polarity: 1: Invert, 0: No Invert
Bit 0: In/Out: 1: Input, 0: Output
CRE5 (GP15, Default 0x01)
Bit 7 - 5: Reserved.
Bit 4 - 3: Select Function.
= 00 Select Basic I/O function.
= 01 General Purpose Write Strobe(Active Low when Bit 1 = 0).
= 10 8042 P12.
= 11 Reserved
Bit 2: Reserved.
Bit 1: Polarity: 1: Invert, 0: No Invert
Bit 0: In/Out: 1: Input, 0: Output
CRE6 (GP16, Default 0x01)
Bit 7 - 5: Reserved.
Bit 4 - 3: Select Function.
= 00 Select Basic I/O function.
= 01 Select 1st alternate function: Watch Dog Timer Output.
= 1x Reserved
Bit 2: Reserved.
Bit 1: Polarity: 1: Invert, 0: No Invert
Bit 0: In/Out: 1: Input, 0: Output
CRE7 (GP17, Default 0x01)
Bit 7 - 4: Reserved.
Bit 4 - 3: Select Function.
= 00 Select Basic I/O function.
= 01 Select 1st alternate function: Power LED output. Please refer to TABLE C
= 1x Reserved
Bit 2: Reserved.
Bit 1: Polarity: 1: Invert, 0: No Invert
Bit 0: In/Out: 1: Input, 0: Output
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TABLE C
POWER LED STATE
WDT_CTRL1* BIT[1]*
WDT_CTRL0* BIT[3]
WDT_CTRL1 BIT[0]
1
X
X
1 Hertz Toggle pulse
0
0
X
Continuous high or low*
0
1
0
Continuous high or low*
0
1
1
1 Hertz Toggle pulse
*Note: 1). Regarding to the contents of WDT_CTR1 and WDT_CTRL0, please refer to CRF3 and CRF4 in Logic Device 8.
2). Continuous high or low depends on the polarity bit of GP13 or GP17 configure registers.
CRF1 ( Default 0x00)
General Purpose Read/Write Enable*
Bit 7 - 2: Reserved
Bit 1:
= 1 Enable General Purpose Write Strobe
= 0 Disable General Purpose Write Strobe
Bit 0:
= 1 Enable General Purpose Address Decode
= 0 Disable General Purpose Address Decode
*Note: If the logical device's activate bit is not set then bit 0 and 1 have no effect.
11.8 Logical Device 8 (GP I/O Port II)
CR30 (Default 0x00)
Bit 7 - 1: Reserved.
Bit 0: = 1 Activates the logical device.
= 0 Logical device is inactive.
CR60, CR 61 (Default 0x00, 0x00)
These two registers select GP2 & Watch Dog I/O base address [0x100:0xFFE] on 2 byte
boundary. I/O base address + 1: Watch Dog I/O base address.
CR70 (Default 0x00)
Bit 7 - 4: Reserved.
Bit 3 - 0: These bits select IRQ resource for Common IRQ of GP20~GP26 at Logic Device 8.
CR72 (Default 0x00)
Bit 7 - 4: Reserved.
Bit 3 - 0: These bits select IRQ resource for Watch Dog.
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CRE8 (GP20, Default 0x01)
Bit 7 - 5: Reserved.
Bit 4 - 3: Select Function.
= 00 Select basic I/O function
= 01 Reserved
= 10 Select alternate function: Keyboard Reset (connected to KBC P20)
= 11 Reserved
Bit 2: Int En
= 1 Enable Common IRQ
= 0 Disable Common IRQ
Bit 1: Polarity: 1: Invert, 0: No Invert
Bit 0: In/Out: 1: Input, 0: Output
CRE9 (GP21, Default 0x01)
Bit 7 - 5: Reserved
Bit 4 - 3: Select Function.
= 00 Select Basic I/O function
= 01 Reserved
= 10 Select 2nd alternate function: Keyboard P13 I/O
= 11 Reserved
Bit 2: Int En
= 1 Enable Common IRQ
= 0 Disable Common IRQ
Bit 1: Polarity: 1: Invert, 0: No Invert
Bit 0: In/Out: 1: Input, 0: Output
CREA (GP22, Default 0x01)
Bit 7 - 5: Reserved.
Bit 4 - 3: Select Function.
= 00 Select Basic I/O function.
= 01 Reserved
= 10 Select 2nd alternate function: Keyboard P14 I/O.
= 11 Reserved
Bit 2: Int En
=1
Enable Common IRQ
=0
Disable Common IRQ
Bit 1: Polarity: 1: Invert, 0: No Invert
Bit 0: In/Out: 1: Input, 0: Output¡ @¡ @
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CREB (GP23, Default 0x01)
Bit 7 - 5: Reserved.
Bit 4 - 3: Select Function.
= 00 Select Basic I/O function
= 01 Reserved
= 10 Select 2nd alternate function: Keyboard P15 I/O
= 11 Reserved
Bit 2: Int En
=1
Enable Common IRQ
=0
Disable Common IRQ
Bit 1: Polarity: 1: Invert, 0: No Invert
Bit 0: In/Out: 1: Input, 0: Output¡ @
CREC (GP24, Default 0x01)
Bit 7 - 5: Reserved.
Bit 4 - 3: Select Function.
= 00 Select Basic I/O function
= 01 Reserved
= 10 Select 2nd alternate function: Keyboard P16 I/O
= 11 Reserved
Bit 2: Int En
=1
Enable Common IRQ
=0
Disable Common IRQ
Bit 1: Polarity: 1: Invert, 0: No Invert
Bit 0: In/Out: 1: Input, 0: Output
CRED (GP25, Default 0x01)
Bit 7 - 4: Reserved.
Bit 3: Select Function.
= 1 Select alternate function: GATE A20(Connect to KBC P21).
= 0 Select basic I/O function
Bit 2: Int En
=1
Enable Common IRQ
=0
Disable Common IRQ
Bit 1: Polarity: 1: Invert, 0: No Invert
Bit 0: In/Out: 1: Input, 0: Output
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CREE (GP26, Default 0x01)
Bit 7 - 3: Reserved.
Bit 2: Int En
=1
Enable Common IRQ
= 0 Disable Common IRQ
Bit 1: Polarity: 1: Invert, 0: No Invert
Bit 0: In/Out: 1: Input, 0: Output
CRF0 (Default 0x00)
Debounce Filter Enable or Disable for General Purpose I/O Combined Interrupt. The Debounce Filter
can reject a pulse with 1ms width or less.
Bit 7 - 4: Reserved
Bit 3: GP Common IRQ Filter Select
= 1 Debounce Filter Enabled
= 0 Debounce Filter Bypassed
Bit 2 - 0: Reserved
CRF1 (Reserved)
CRF2 (Default 0x00)
Watch Dog Timer Time-out value. Writing a non-zero value to this register causes the counter to load
the value to Watch Dog Counter and start to count down. If the Bit2 and Bit 1 are set, any Mouse
Interrupt or Keyboard Interrupt happen will also cause to reload the non-zero value to Watch Dog
Counter and count down. Read this register can not access Watch Dog Timer Time-out value, but
can access the current value in Watch Dog Counter.
Bit 7 - 0:
= 0x00 Time-out Disable
= 0x01 Time-out occurs after 1 minute
= 0x02 Time-out occurs after 2 minutes
= 0x03 Time-out occurs after 3 minutes
................................................
= 0xFF Time-out occurs after 255 minutes
CRF3 (WDT_CTRL0, Default 0x00)
Watch Dog Timer Control Register #0
Bit 7 - 4: Reserved
Bit 3: When Time-out occurs, Enable or Disable Power LED with 1 Hz and 50% duty cycle output.
= 1 Enable
= 0 Disable
Bit 2: Mouse interrupt reset Enable or Disable
= 1 Watch Dog Timer is reset upon a Mouse interrupt
= 0 Watch Dog Timer is not affected by Mouse interrupt
Bit 1: Keyboard interrupt reset Enable or Disable
= 1 Watch Dog Timer is reset upon a Keyboard interrupt
= 0 Watch Dog Timer is not affected by Keyboard interrupt
Bit 0: Reserved.
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CRF4 (WDT_CTRL1, Default 0x00)
Watch Dog Timer Control Register #1
Bit 7 - 4: Reserved
Bit 3: Enable the rising edge of Keyboard Reset(P20) to force Time-out event, R/W*
= 1 Enable
= 0 Disable
Bit 2: Force Watch Dog Timer Time-out, Write only*
= 1 Force Watch Dog Timer time-out event; this bit is self-clearing.
Bit 1: Enable Power LED 1Hz rate toggle pulse with 50% duty cycle , R/W
= 1 Enable
= 0 Disable
Bit 0: Watch Dog Timer Status, R/W
= 1 Watch Dog Timer time-out occurred.
= 0 Watch Dog Timer counting
*Note: 1). Internal logic provides an 1us Debounce Filter to reject the width of P20 pulse less than 1us.
2). The P20 signal that coming from Debounce Filter is ORed with the signal generated by the Force Time-out bit and then
connect to set the Bit 0(Watch Dog Timer Status). The ORed signal is self-clearing.
11.9 Logical Device 9 (GP I/O Port III)
CR30 (Default 0x00)
Bit 7 - 1: Reserved.
Bit 0: = 1 Activates the logical device.
= 0 Logical device is inactive.
CR60, CR 61 (Default 0x00, 0x00)
These two registers select GP3 I/O base address [0x100:0xFFF] on 1 byte boundary.
CR62, CR 63 (Default 0x00, 0x00)
These two registers select GP32 alternate function Primary I/O base address [0x100:0xFFE] on 2byte boundary; They are available as you setting GP32 to be an alternate function (General
Purpose Address Decode).
CR64, CR 65 (Default 0x00, 0x00)
These two registers select GP33 alternate function Primary I/O base address [0x100:0xFFF] on 2byte boundary; They are available as you setting GP33 to be an alternate function (General
Purpose Address Decode).
CR70 (Default 0x00)
Bit 7 - 4: Reserved.
Bit 3 - 0: These bits select IRQ resource for GP30 as you setting GP30 to be an alternate function
(Interrupt Steering).
CR72 (Default 0x00)
Bit 7 - 4: Reserved.
Bit 3 - 0: These bits select IRQ resource for GP31 as you setting GP31 to be an alternate function
(Interrupt Steering).
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CRE0 (GP30, Default 0x01)
Bit 7 - 5: Reserved.
Bit 4: IRQ Filter Select
= 1 Debounce Filter Enabled.
= 0 Debounce Filter Bypassed.
Bit 3: Select Function.
= 1 Select Alternate Function: Interrupt Steering.
= 0 Select Basic I/O Function.
Bit 2: Reserved.
Bit 1: Polarity.
= 1 Invert.
= 0 No Invert.
Bit 0: In/Out selection.
= 1 Input.
= 0 Output.
CRE1 (GP31, Default 0x01)
Bit 7 - 5: Reserved.
Bit 4: IRQ Filter Select
= 1 Debounce Filter Enabled
= 0 Debounce Filter Bypassed
Bit 3: Select Function.
= 1 Select Alternate Function: Interrupt Steering.
= 0 Select Basic I/O Function.
Bit 2: Reserved.
Bit 1: Polarity.
= 1 Invert.
= 0 No Invert.
Bit 0: In/Out selection.
= 1 Input.
= 0 Output.
CRE2 (GP32, Default 0x01)
Bit 7 - 4: Reserved.
Bit 3: Select Function.
= 1 Select Alternate Function: General Purpose Address Decode.
= 0 Select Basic I/O Function.
Bit 2: Reserved.
Bit 1: Polarity: 1: Invert, 0: No Invert
Bit 0: In/Out: 1: Input, 0: Output
CRE3 (GP33, Default 0x01)
Bit 7 - 4: Reserved.
Bit 3: Select Function.
= 1 Select Alternate Function: General Purpose Address Decode.
= 0 Select Basic I/O Function.
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Bit 2: Reserved.
Bit 1: Polarity: 1: Invert, 0: No Invert
Bit 0: In/Out: 1: Input, 0: Output
CRE4 (GP34, Default 0x01)
Bit 7 - 4: Reserved.
Bit 3: Select Function.
= 1 Select Alternate Function: Watch Dog Timer output.
= 0 Select Basic I/O Function.
Bit 2: Reserved.
Bit 1: Polarity: 1: Invert, 0: No Invert
Bit 0: In/Out: 1: Input, 0: Output
CRE5 (GP35, Default 0x01)
Bit 7 - 2: Reserved.
Bit 1: Polarity: 1: Invert, 0: No Invert
Bit 0: In/Out: 1: Input, 0: Output
CRE6 (GP36, Default 0x01)
Bit 7 - 2: Reserved.
Bit 1: Polarity: 1: Invert, 0: No Invert
Bit 0: In/Out: 1: Input, 0: Output
CRE7 (GP37, Default 0x01)
Bit 7 - 2: Reserved.
Bit 1: Polarity: 1: Invert, 0: No Invert
Bit 0: In/Out: 1: Input, 0: Output
CRF1 ( Default 0x00)
Bit 7 - 3: Reserved
Bit 2: SERIRQ
= 0 The IRQ system is in normal mode.
= 1 The IRQ system is in serial IRQ mode.
Bit 1:
= 1 Enable GP33 General Purpose Address Decode.
= 0 Disable GP33 General Purpose Address Decode.
Bit 0:
= 1 Enable GP32 General Purpose Address Decode.
= 0 Disable GP32 General Purpose Address Decode.
*Note: If the logical device's activate bit is not set then bit 0 and 1 have no effect.
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11.10 Logical Device A (ACPI)
CR30 (Default 0x00)
Bit 7 - 1: Reserved.
Bit 0: = 1 Activates the logical device.
= 0 Logical device is inactive.
CR60, CR 61 (Default 0x00, 0x00)
These two registers select PM1 register block base address [0x100:0xFF0] on 16-byte boundary.
CR62, CR 63 (Default 0x00, 0x00)
These two registers select GPE0 register block base address [0x100:0xFFC] on 4-byte boundary.
CR64, CR 65 (Default 0x00, 0x00)
These two registers select GPE1 register block base address [0x100:0xFFC] on 4-byte boundary.
CR70 (Default 0x00)
Bit 7 - 4: Reserved.
Bit 3 - 0: These bits select IRQ resource for SCI .
CRE0 (Default 0x00)
Bit 7: DIS-PANSWIN. Disable panel switch input to turn system power supply on.
=0
PANSWIN is wire-ANDed and connected to PANSWOUT .
=1
PANSWIN is blocked and can not affect PANSWOUT .
Bit 6: ENKBWAKEUP. Enable Keyboard to wake-up system via PANSWOUT .
=0
Disable Keyboard wake-up function.
=1
Enable Keyboard wake-up function.
Bit 5: ENMSWAKEUP. Enable Mouse to wake-up system via PANSWOUT .
=0
Disable Mouse wake-up function.
=1
Enable Mouse wake-up function.
Bit 4: MSRKEY. Select Mouse Left/Right Botton to wake-up system via PANSWOUT .
=0
Select click on Mouse Left-botton twice to wake the system up.
=1
Select click on Mouse right-botton twice to wake the system up.
Bit 3: Reserved.
Bit 2: KB/MS Swap. Enable Keyboard/Mouse port-swap.
=0
Keyboard/Mouse ports are not swapped.
=1
Keyboard/Mouse ports are swapped.
Bit 1: MSXKEY. Enable any character received from Mouse to wake-up the system.
=0
Just clicking Mouse left/right-botton twice can wake the system up.
=1
Any character received from Mouse can wake the system up (the setting of Bit 4 is
ignored).
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Bit 0: KBXKEY. Enable any character received from Keyboard to wake-up the system.
=0
Only predetermined specific key combination can wake up the system.
=1
Any character received from Keyboard can wake up the system.
CRE1 (Default 0x00) Keyboard Wake-up Index Register
This register is used to indicate which Keyboard Wake-up Shift register or Predetermined key
Register is to be read/written via CRE2.
CRE2 Keyboard Wake-up Data Register
CRE3 (Read only) Keyboard/Mouse Wake-up Status Register
Bit 7-3: Reserved.
Bit 2: PANSW_STS. The Panel switch event is caused by PANSWIN . This bit is cleared by
reading this register.
Bit 1: Mouse_STS. The Panel switch event is caused by Mouse wake-up event. This bit is
cleared by reading this register.
Bit 0: Keyboard_STS. The Panel switch event is caused by Keyboard wake-up event. This bit is
cleared by reading this register.
CRE4 This Register is reserved for test.
CRF0 (Default 0x00)
Bit 7: CHIPPME. Chip level power management enable.
=0
disable the ACPI/Legacy and the auto power management functions
=1
enable the ACPI/Legacy and the auto power management functions.
Bit 6 - 4: Reserved. Return zero when read.
Bit 3: PRTPME. Printer port power management enable.
=0
disable the auto power management functions.
=1
enable the auto power management functions provided
CRF0.bit7 (CHIPPME) is also set to 1.
Bit 2: FDCPME. FDC power management enable.
=0
disable the auto power management functions.
=1
enable the auto power management functions provided
CRF0.bit7 (CHIPPME) is also set to 1.
Bit 1: URAPME. UART A power management enable.
=0
disable the auto power management functions.
=1
enable the auto power management functions provided
CRF0.bit7 (CHIPPME) is also set to 1.
Bit 0: URBPME. UART B power management enable.
=0
disable the auto power management functions.
=1
enable the auto power management functions provided
CRF0.bit7 (CHIPPME) is also set to 1.
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CRF1 (Default 0x00)
Bit 7 - 4: Reserved. Return zero when read.
Bit 3 - 0: Devices' idle status.
These bits indicate that the individual device's idle timer expires due to no I/O access, no IRQ,
and no external input to the device. These 4 bits are controlled by the printer port, FDC, UART A,
and UART B power down machines individually. Writing a 1 clears this bit, and writing a 0 has no
effect. Note that: the user is not supposed to change the status while the power management
function is enabled.
Bit 3: PRTIDLSTS. Printer port idle status.
=0
printer port is now in the working state.
=1
printer port is now in the sleeping state due to no printer port access, no IRQ, no DMA
acknowledge, and no transition on BUSY, ACK , PE, SLCT, and ERR pins in a
preset expiry time period.
Bit 2: FDCIDLSTS. FDC idle status.
=0
FDC is now in the working state.
=1
FDC is now in the sleeping state due to no FDC access, no IRQ, no DMA
acknowledge, and no enabling of the motor enable bits in the DOR register in a
preset expiry time period.
Bit 1: URAIDLSTS. UART A idle status.
=0
UART A is now in the working state.
=1
UART A is now in the sleeping state due to no UART A access, no IRQ, the receiver
is now waiting for a start bit, the transmitter shift register is now empty, and no
transition on MODEM control input lines in a preset expiry time period.
Bit 0: URBIDLSTS. UART B idle status.
=0
UART B is now in the working state.
=1
UART B is now in the sleeping state due to no UART A access, no IRQ, the receiver
is now waiting for a start bit, the transmitter shift register is now empty, and no
transition on MODEM control input lines in a preset expiry time period.
CRF2 (Default 0x00)
Bit 7 - 4: Reserved. Return zero when read.
Bit 3 - 0: Devices' trap status.
These bits indicate that the individual device wakes up due to any I/O access, IRQ, and external
input to the device. The device's idle timer reloads the preset expiry depending on which device
wakes up. These 4 bits are controlled by the printer port, FDC, UART A, and UART B power down
machines respectively. Writing a 1 clears this bit, and writing a 0 has no effect. Note that: the
user is not supposed to change the status while power management function is enabled.
Bit 3: PRTTRAPSTS. Printer port trap status.
=0
the printer port is now in the sleeping state.
=1
the printer port is now in the working state due to any printer port access, any IRQ,
any DMA acknowledge, and any transition on BUSY, ACK , PE, SLCT, and ERR
pins.
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Bit 2: FDCTRAPSTS. FDC trap status.
=0
FDC is now in the sleeping state.
=1
FDC is now in the working state due to any FDC access, any IRQ, any DMA
acknowledge, and any enabling of the motor enable bits in the DOR register.
Bit 1: URATRAPSTS. UART A trap status.
=0
UART A is now in the sleeping state.
=1
UART A is now in the working state due to any UART A access, any IRQ, the
receiver begins receiving a start bit, the transmitter shift register begins transmitting a
start bit, and any transition on MODEM control input lines.
Bit 0: URBTRAPSTS. UART B trap status.
=0
UART B is now in the sleeping state.
=1
UART B is now in the working state due to any UART B access, any IRQ, the
receiver begins receiving a start bit, the transmitter shift register begins transmitting
a start bit, and any transition on MODEM control input lines.
CRF3 (Default 0x00)
Bit 7 - 6: Reserved. Return zero when read.
Bit 5 - 0: Device's IRQ status.
These bits indicate the IRQ status of the individual device. The device's IRQ status
by their source device and is cleared by writing a 1. Writing a 0 has no effect.
bit is set
Bit 5: MOUIRQSTS. MOUSE IRQ status.
Bit 4: KBCIRQSTS. KBC IRQ status.
Bit 3: PRTIRQSTS. printer port IRQ status.
Bit 2: FDCIRQSTS. FDC IRQ status.
Bit 1: URAIRQSTS. UART A IRQ status.
Bit 0: URBIRQSTS. UART B IRQ status.
CRF4 (Default 0x00)
Bit 7 - 4: Reserved. Return zero when read.
Bit 3 - 0: Enable bits of the SMI generation due to the device's idleness.
These bits enable the generation of an SMI interrupt due to the expiration of the device's idle
timer. These 4 bits control the printer port, FDC, UART A, and UART B SMI logics respectively.
Bit 3: PRTIDLEN.
=0
disable the generation of an SMI interrupt due to printer port's idleness.
=1
enable the generation of an SMI interrupt due to printer port's idleness.
Bit 2: FDCIDLEN.
=0
disable the generation of an SMI interrupt due to FDC's idleness.
=1
enable the generation of an SMI interrupt due to FDC's idleness.
-120-
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
Bit 1: URAIDLEN.
=0
disable the generation of an SMI interrupt due to UART A's idleness.
=1
enable the generation of an SMI interrupt due to UART A's idleness.
Bit 0: URBIDLEN.
=0
disable the generation of an SMI interrupt due to UART B's idleness.
=1
enable the generation of an SMI interrupt due to UART B's idleness.
CRF5 (Default 0x00)
Bit 7 - 4: Reserved. Return zero when read.
Bit 3 - 0: Enable bits of the SMI generation due to device's trap.
These bits enable the generation of an SMI interrupt due to any I/O access, IRQ, and external
input to the device. These 4 bits control the printer port, FDC, UART A, and UART B SMI logics
respectively.
Bit 3: PRTTRAPEN.
=0
disable the generation of an SMI interrupt due to printer port's trap.
=1
enable the generation of an SMI interrupt due to printer port's trap.
Bit 2: FDCTRAPEN.
=0
disable the generation of an SMI interrupt due to FDC's trap.
=1
enable the generation of an SMI interrupt due to FDC's trap.
Bit 1: URATRAPEN.
=0
disable the generation of an SMI interrupt due to UART A's trap.
=1
enable the generation of an SMI interrupt due to UART A's trap.
Bit 0: URBTRAPEN.
=0
disable the generation of an SMI interrupt due to UART B's trap.
=1
enable the generation of an SMI interrupt due to UART B's trap.
CRF6 (Default 0x00)
Bit 7 - 6: Reserved. Return zero when read.
Bit 5 - 0: Enable bits of the SMI generation due to the device's IRQ.
These bits enable the generation of an SMI interrupt due to any IRQ of the devices. These 4 bits
control the printer port, FDC, UART A, and UART B SMI logics respectively. The SMI logic
output for the IRQs is as follows:
SMI logic output = (URBIRQEN and URBIRQSTS) or (URAIRQEN and URAIRQSTS) or
(FDCIRQEN and FDCIRQSTS) or (PRTIRQEN and PRTIRQSTS)
(KBCIRQEN and KBCIRQSTS) or (MOUIRQEN and MOUIRQSTS)
-121-
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
Bit 5: MOUIRQEN.
=0
disable the generation of an SMI interrupt due to MOUSE's IRQ.
=1
enable the generation of an SMI interrupt due to MOUSE's IRQ.
Bit 4: KBCIRQEN.
=0
disable the generation of an SMI interrupt due to KBC's IRQ.
=1
enable the generation of an SMI interrupt due to KBC's IRQ.
Bit 3: PRTIRQEN.
=0
disable the generation of an SMI interrupt due to printer port's IRQ.
=1
enable the generation of an SMI interrupt due to printer port's IRQ.
Bit 2: FDCIRQEN.
=0
disable the generation of an SMI interrupt due to FDC's IRQ.
=1
enable the generation of an SMI interrupt due to FDC's IRQ.
Bit 1: URAIRQEN.
=0
disable the generation of an SMI interrupt due to UART A's IRQ.
=1
enable the generation of an SMI interrupt due to UART A's IRQ.
Bit 0: URBIRQEN.
=0
disable the generation of an SMI interrupt due to UART B's IRQ.
=1
enable the generation of an SMI interrupt due to UART B's IRQ.
CRF7 (Default 0x00)
Bit 7 - 1: Reserved. Return zero when read.
Bit 0: SMI_EN.
This bit is the SMI output pin enable bit. When an SMI event is raised on the output of the SMI
logic, setting this bit enables the SMI interrupt to be generated on the pin SMI . If this bit is
cleared, only the IRQ status bit in CRF3 is set, and no SMI interrupt is generated on the pin SMI .
=0
Disable SMI
=1
Enable SMI
CRFE, FF (Default 0x00)
Reserved for Winbond test.
-122-
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
12.0 SPECIFICATIONS
12.1 Absolute Maximum Ratings
PARAMETER
RATING
UNIT
-0.5 to 7.0
V
-0.5 to VDD+0.5
V
Battery Voltage VBAT
4.0 to 1.8
V
Operating Temperature
0 to +70
°C
-55 to +150
°C
Power Supply Voltage
Input Voltage
Storage Temperature
Note: Exposure to conditions beyond those listed under Absolute Maximum Ratings may adversely affect the life and reliability of the
device.
12.2 DC CHARACTERISTICS
(Ta = 0° C to 70° C, VDD = 5V ± 10%, VSS = 0V)
MAX.
UNIT
IBAT
2.4
uA
VBAT = 2.5 V
IBAT
2.0
mA
VSB = 5.0 V, All ACPI pins are
not connected.
PARAMETER
SYM.
Battery Quiescent Current
Stand-by Power Supply
Quiescent Current
MIN.
TYP.
CONDITIONS
I/O8t - TTL level bi-directional pin with source-sink capability of 8 mA
Input Low Voltage
VIL
Input High Voltage
VIH
Output Low Voltage
VOL
Output High Voltage
VOH
Input High Leakage
ILIH
Input Low Leakage
ILIL
0.8
2.0
V
V
0.4
V
IOL = 8 mA
V
IOH = - 8 mA
+10
µA
VIN = VDD
-10
µA
VIN = 0V
2.4
I/O6t - TTL level bi-directional pin with source-sink capability of 6 mA
Input Low Voltage
VIL
Input High Voltage
VIH
Output Low Voltage
VOL
Output High Voltage
VOH
Input High Leakage
ILIH
Input Low Leakage
ILIL
0.8
2.0
V
V
0.4
V
IOL = 6 mA
V
IOH = - 6 mA
+10
µA
VIN = VDD
-10
µA
VIN = 0V
2.4
- 123 -
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
12.2 DC CHARACTERISTICS, continued
PARAMETER
SYM.
MIN.
TYP.
MAX.
UNIT
CONDITIONS
I/O8 - CMOS level bi-directional pin with source-sink capability of 8 mA
Input Low Voltage
VIL
Input High Voltage
VIH
Output Low Voltage
VOL
Output High Voltage
VOH
Input High Leakage
ILIH
Input Low Leakage
ILIL
0.3xVDD
0.7xVDD
V
V
0.4
V
IOL = 8 mA
V
IOH = - 8 mA
+ 10
µA
VIN = VDD
- 10
µA
VIN = 0V
3.5
I/O12 - CMOS level bi-directional pin with source-sink capability of 12 mA
Input Low Voltage
VIL
Input High Voltage
VIH
Output Low Voltage
VOL
Output High Voltage
VOH
Input High Leakage
ILIH
Input Low Leakage
ILIL
0.3xVDD
0.7xVDD
V
V
0.4
V
IOL = 12 mA
V
IOH = - 12 mA
+ 10
µA
VIN = VDD
- 10
µA
VIN = 0V
3.5
I/O16u - CMOS level bi-directional pin with source-sink capability of 16 mA, with internal pull-up
resistor
Input Low Voltage
VIL
Input High Voltage
VIH
Output Low Voltage
VOL
Output High Voltage
VOH
Input High Leakage
ILIH
Input Low Leakage
ILIL
0.3xVDD
0.7xVDD
V
V
0.4
V
IOL = 16 mA
V
IOH = - 16 mA
+ 10
µA
VIN = VDD
- 10
µA
VIN = 0V
3.5
I/OD16u - CMOS level Open-Drain pin with source-sink capability of 16 mA, with internal pull-up
resistor
Input Low Voltage
VIL
Input High Voltage
VIH
Output Low Voltage
VOL
Output High Voltage
VOH
Input High Leakage
ILIH
Input Low Leakage
ILIL
0.3xVDD
0.7xVDD
V
V
0.4
V
IOL = 16 mA
V
IOH = - 16 mA
+ 10
µA
VIN = VDD
- 10
µA
VIN = 0V
3.5
- 124 -
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
12.2 DC CHARACTERISTICS, continued
PARAMETER
SYM.
MIN.
TYP.
MAX.
UNIT
CONDITIONS
I/O12t - TTL level bi-directional pin with source-sink capability of 12 mA
Input Low Voltage
VIL
Input High Voltage
VIH
Output Low Voltage
VOL
Output High Voltage
VOH
Input High Leakage
ILIH
Input Low Leakage
ILIL
0.8
V
2.0
V
0.4
V
IOL = 12 mA
V
IOH = - 12 mA
+ 10
µA
VIN = VDD
- 10
µA
VIN = 0V
2.4
I/O24t - TTL level bi-directional pin with source-sink capability of 24 mA
Input Low Voltage
VIL
Input High Voltage
VIH
Output Low Voltage
VOL
Output High Voltage
VOH
Input High Leakage
ILIH
Input Low Leakage
ILIL
0.8
V
2.0
V
0.4
V
IOL = 24 mA
V
IOH = - 24 mA
+ 10
µA
VIN = VDD
- 10
µA
VIN = 0V
V
IOL = 8 mA
V
IOH = - 8 mA
2.4
OUT8t - TTL level output pin with source-sink capability of 8 mA
Output Low Voltage
VOL
Output High Voltage
VOH
0.4
2.4
OUT12t - TTL level output pin with source-sink capability of 12 mA
Output Low Voltage
VOL
Output High Voltage
VOH
0.4
V
IOL = 12 mA
V
IOH = -12 mA
V
IOL = 12 mA
0.4
V
IOL = 24 mA
0.8
V
2.4
OD12 - Open-drain output pin with sink capability of 12 mA
Output Low Voltage
VOL
0.4
OD24 - Open-drain output pin with sink capability of 24 mA
Output Low Voltage
VOL
INt - TTL level input pin
Input Low Voltage
VIL
Input High Voltage
VIH
Input High Leakage
ILIH
+10
µA
VIN = VDD
Input Low Leakage
ILIL
-10
µA
VIN = 0 V
2.0
V
- 125 -
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
12.2 DC CHARACTERISTICS, continued
PARAMETER
SYM.
MIN.
TYP.
MAX.
UNIT
0.3×VDD
V
CONDITIONS
INc - CMOS level input pin
Input Low Voltage
VIL
Input High Voltage
VIH
Input High Leakage
ILIH
+10
µA
VIN = VDD
Input Low Leakage
ILIL
-10
µA
VIN = 0 V
V
0.7×VDD
INcs - CMOS level Schmitt-triggered input pin
Input Low Threshold Voltage
Vt-
1.3
1.5
1.7
V
VDD = 5 V
Input High Threshold Voltage
Vt+
3.2
3.5
3.8
V
VDD = 5 V
Hystersis
VTH
1.5
2
V
VDD = 5 V
Input High Leakage
ILIH
+10
µA
VIN = VDD
Input Low Leakage
ILIL
-10
µA
VIN = 0 V
0.7xVDD
V
INcu - CMOS level input pin with internal pull-up resistor
Input Low Voltage
VIL
Input High Voltage
VIH
Input High Leakage
ILIH
+10
µA
VIN = VDD
Input Low Leakage
ILIL
-10
µA
VIN = 0 V
0.7xVDD
V
INts - TTL level Schmitt-triggered input pin
Input Low Threshold Voltage
Vt-
0.5
0.8
1.1
V
VDD = 5 V
Input High Threshold Voltage
Vt+
1.6
2.0
2.4
V
VDD = 5 V
Hystersis
VTH
0.5
1.2
V
VDD = 5 V
Input High Leakage
ILIH
+10
µA
VIN = VDD
Input Low Leakage
ILIL
-10
µA
VIN = 0 V
INtsu - TTL level Schmitt-triggered input pin with internal pull-up resistor
Input Low Threshold Voltage
Vt-
0.5
0.8
1.1
V
VDD = 5 V
Input High Threshold Voltage
Vt+
1.6
2.0
2.4
V
VDD = 5 V
Hystersis
VTH
0.5
1.2
V
VDD = 5 V
Input High Leakage
ILIH
+10
µA
VIN = VDD
Input Low Leakage
ILIL
-10
µA
VIN = 0 V
- 126 -
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
12.3 AC Characteristics
12.3.1 FDC: Data rate = 1 MB, 500 KB, 300 KB, 250 KB/sec.
PARAMETER
SYM.
TEST
CONDITIONS
MIN.
TYP.
MAX.
UNIT
(NOTE 1)
SA9-SA0, AEN, DACK ,
CS , setup time to IOR ¡ õ
TAR
25
nS
SA9-SA0, AEN, DACK ,
hold time for IOR¡ ô
TAR
0
nS
IOR width
TRR
80
nS
Data access time from
IOR ¡ õ
TFD
CL = 100 pf
Data hold from IOR¡ õ
TDH
CL = 100 pf
10
SD to from IOR ¡ ô
TDF
CL = 100 pf
10
IRQ delay from IOR¡ ô
TRI
SA9-SA0, AEN, DACK ,
setup time to IOW ¡ õ
TAW
25
nS
SA9-SA0, AEN, DACK ,
hold time for IOW ¡ ô
TWA
0
nS
IOW width
TWW
60
nS
Data setup time to IOW ¡ ô
TDW
60
nS
Data hold time from
IOW ¡ ô
TWD
0
nS
IRQ delay from IOW ¡ ô
TWI
80
nS
nS
50
nS
360/570
/675
nS
360/570
/675
nS
µS
DRQ cycle time
TMCY
27
DRQ delay time DACK ¡ õ
TAM
DRQ to DACK delay
TMA
0
nS
DACK width
TAA
260/430
/510
nS
IOR delay from DRQ
TMR
0
nS
IOW delay from DRQ
TMW
0
nS
50
- 127 -
nS
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
12.3.1 AC Characteristics, FDC continued
PARAMETER
SYM.
IOW or IOR response time
from DRQ
TMRW
TEST
CONDITIONS
MIN.
TYP.
(NOTE 1)
MAX.
UNIT
µS
6/12
/20/24
TC width
TTC
135/220
/260
nS
RESET width
TRST
1.8/3/3.
5
µS
INDEX width
TIDX
0.5/0.9
/1.0
µS
DIR setup time to STEP
TDST
1.0/1.6
/2.0
µS
DIR hold time from STEP
TSTD
24/40/48
µS
STEP pulse width
TSTP
6.8/11.5
/13.8
7/11.7
/14
7.2/11.9
/14.2
µS
STEP cycle width
TSC
Note 2
Note 2
Note 2
µS
WD pulse width
TWDD
100/185
/225
125/210
/250
150/235
/275
µS
Write precompensation
TWPC
100/138
/225
125/210
/250
150/235
/275
µS
Notes:
1. Typical values for T = 25° C and normal supply voltage.
2. Programmable from 2 mS through 32 mS in 2 mS increments.
- 128 -
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
12.3.2 UART/Parallel Port
PARAMETER
SYMBOL
Delay from Stop to Set Interrupt
TSINT
Delay from IOR Reset Interrupt
TRINT
Delay from Initial IRQ Reset to
Transmit Start
TIRS
Delay from IOW to Reset interrupt
THR
Delay from Initial IOW to interrupt
TSI
Delay from Stop to Set Interrupt
TSTI
Delay from IOR to Reset Interrupt
TIR
TMWO
Delay from IOR to Output
TEST
CONDITIONS
MIN.
MAX.
9/16
UNIT
Baud
Rate
1
µS
8/16
Baud
Rate
175
nS
16/16
Baud
Rate
1/2
Baud
Rate
100 pF Loading
250
nS
100 pF Loading
200
nS
100 pf Loading
1/16
100 pf Loading
9/16
Set Interrupt Delay from Modem
Input
TSIM
250
nS
Reset Interrupt Delay from IOR
TRIM
250
nS
Interrupt Active Delay
TIAD
100 pF Loading
25
nS
Interrupt Inactive Delay
TIID
100 pF Loading
30
nS
N
100 pF Loading
216-1
Baud Divisor
12.3.3 Parallel Port Mode Parameters
PARAMETER
SYM.
MIN.
TYP.
MAX.
UNIT
PD0-7, INDEX, STROBE, AUTOFD Delay from
IOW
t1
100
nS
IRQ Delay from ACK , nFAULT
t2
60
nS
IRQ Delay from IOW
t3
105
nS
IRQ Active Low in ECP and EPP Modes
t4
300
nS
ERROR Active to IRQ Active
t5
105
nS
- 129 -
200
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
12.3.4 EPP Data or Address Read Cycle Timing Parameters
PARAMETER
SYM.
MIN.
MAX.
UNIT
Ax Valid to IOR Asserted
t1
40
nS
IOCHRDY Deasserted to IOR Deasserted
t2
0
nS
IOR Deasserted to Ax Valid
t3
10
IOR Deasserted to IOW or IOR Asserted
t4
40
IOR Asserted to IOCHRDY Asserted
t5
PD Valid to SD Valid
10
nS
0
24
nS
t6
0
75
nS
IOR Deasserted to SD Hi-Z (Hold Time)
t7
0
40
µS
SD Valid to IOCHRDY Deasserted
t8
0
85
nS
WAIT Deasserted to IOCHRDY Deasserted
t9
60
160
nS
PD Hi-Z to PDBIR Set
t10
0
nS
WRITE Deasserted to IOR Asserted
t13
0
nS
WAIT Asserted to WRITE Deasserted
t14
0
185
nS
Deasserted to WRITE Modified
t15
60
190
nS
IOR Asserted to PD Hi-Z
t16
0
50
nS
WAIT Asserted to PD Hi-Z
t17
60
180
nS
Command Asserted to PD Valid
t18
0
nS
Command Deasserted to PD Hi-Z
t19
0
nS
WAIT Deasserted to PD Drive
t20
60
WRITE Deasserted to Command
t21
1
PBDIR Set to Command
t22
0
20
nS
PD Hi-Z to Command Asserted
t23
0
30
nS
Asserted to Command Asserted
t24
0
195
nS
WAIT Deasserted to Command Deasserted
t25
60
180
nS
Time out
t26
10
12
nS
PD Valid to WAIT Deasserted
t27
0
nS
PD Hi-Z to WAIT Deasserted
t28
0
µS
- 130 -
190
nS
nS
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
12.3.5 EPP Data or Address Write Cycle Timing Parameters
PARAMETER
SYM.
MIN.
MAX.
UNIT
Ax Valid to IOW Asserted
t1
40
nS
SD Valid to Asserted
t2
10
nS
IOW Deasserted to Ax Invalid
t3
10
nS
WAIT Deasserted to IOCHRDY Deasserted
t4
0
nS
Command Asserted to WAIT Deasserted
t5
10
nS
IOW Deasserted to IOW or IOR Asserted
t6
40
nS
IOCHRDY Deasserted to IOW Deasserted
t7
0
24
nS
WAIT Asserted to Command Asserted
t8
60
160
nS
IOW Asserted to WAIT Asserted
t9
0
70
nS
PBDIR Low to WRITE Asserted
t10
0
WAIT Asserted to WRITE Asserted
t11
60
185
nS
WAIT Asserted to WRITE Change
t12
60
185
nS
IOW Asserted to PD Valid
t13
0
50
nS
WAIT Asserted to PD Invalid
t14
0
nS
PD Invalid to Command Asserted
t15
10
nS
IOW to Command Asserted
t16
5
35
nS
WAIT Asserted to Command Asserted
t17
60
210
nS
WAIT Deasserted to Command Deasserted
t18
60
190
nS
Command Asserted to WAIT Deasserted
t19
0
10
µS
Time out
t20
10
12
µS
Command Deasserted to WAIT Asserted
t21
0
nS
IOW Deasserted to WRITE Deasserted and PD invalid
t22
0
nS
- 131 -
nS
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
12.3.6 Parallel Port FIFO Timing Parameters
PARAMETER
SYMBOL
MIN.
MAX.
UNIT
DATA Valid to nSTROBE Active
t1
600
nS
nSTROBE Active Pulse Width
t2
600
nS
DATA Hold from nSTROBE Inactive
t3
450
nS
BUSY Inactive to PD Inactive
t4
80
nS
BUSY Inactive to nSTROBE Active
t5
680
nS
nSTROBE Active to BUSY Active
t6
500
nS
12.3.7 ECP Parallel Port Forward Timing Parameters
PARAMETER
SYMBOL
MIN.
MAX.
UNIT
nAUTOFD Valid to nSTROBE Asserted
t1
0
60
nS
PD Valid to nSTROBE Asserted
t2
0
60
nS
BUSY Deasserted to nAUTOFD Changed
t3
80
180
nS
BUSY Deasserted to PD Changed
t4
80
180
nS
nSTROBE Deasserted to BUSY Deasserted
t5
0
BUSY Deasserted to nSTROBE Asserted
t6
80
nSTROBE Asserted to BUSY Asserted
t7
0
BUSY Asserted to nSTROBE Deasserted
t8
80
180
MIN.
MAX.
nS
200
nS
nS
nS
12.3.8 ECP Parallel Port Reverse Timing Parameters
PARAMETER
SYMBOL
UNIT
PD Valid to nACK Asserted
t1
0
nS
nAUTOFD Deasserted to PD Changed
t2
0
nS
nAUTOFD Asserted to nACK Asserted
t3
0
nS
nAUTOFD Deasserted to nACK Deasserted
t4
0
nS
nACK Deasserted to nAUTOFD Asserted
t5
80
200
nS
PD Changed to nAUTOFD Deasserted
t6
80
200
nS
- 132 -
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
12.3.9 KBC Timing Parameters
NO.
DESCRIPTION
MIN.
MAX.
UNIT
T1
Address Setup Time from WRB
0
nS
T2
Address Setup Time from RDB
0
nS
T3
WRB Strobe Width
20
nS
T4
RDB Strobe Width
20
nS
T5
Address Hold Time from WRB
0
nS
T6
Address Hold Time from RDB
0
nS
T7
Data Setup Time
50
nS
T8
Data Hold Time
0
nS
T9
Gate Delay Time from WRB
10
T10
RDB to Drive Data Delay
T11
RDB to Floating Data Delay
T12
Data Valid After Clock Falling (SEND)
T13
K/B Clock Period
20
µS
T14
K/B Clock Pulse Width
10
µS
T15
Data Valid Before Clock Falling (RECEIVE)
4
µS
T16
K/B ACK After Finish Receiving
20
µS
T17
RC Fast Reset Pulse Delay (8 Mhz)
2
T18
RC Pulse Width (8 Mhz)
6
T19
Transmit Timeout
T20
Data Valid Hold Time
0
T21
Input Clock Period (6−12 Mhz)
83
167
nS
T22
Duration of CLK inactive
30
50
µS
T23
Duration of CLK active
30
50
µS
T24
Time from inactive CLK transition, used to time when
the auxiliary device sample DATA
5
25
µS
T25
Time of inhibit mode
100
300
µS
T26
Time from rising edge of CLK to DATA transition
5
T28-5
µS
T27
Duration of CLK inactive
30
50
µS
T28
Duration of CLK active
30
50
µS
T29
Time from DATA transition to falling edge of CLK
5
25
µS
0
30
nS
40
nS
20
nS
4
µS
3
µS
2
- 133 -
µS
mS
µS
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
12.3.10 GPIO Timing Parameters
SYMBOL
tWGO
PARAMETER
MIN.
Write data to GPIO update
MAX.
UNIT
300(Note 1)
ns
MAX.
UNIT
Note : Refer to Microprocessor Interface Timing for Read Timing.
12.3.11 Keyboard/Mouse Timing Parameters
SYMBOL
PARAMETER
MIN.
tSWL
PANSWIN falling edge to PANSWOUT falling edge
20
ns
tSWH
PANSWIN falling edge to PANSWOUT Hi-Z
50
ns
tWKUPD
KCLK/MCLK falling edge to PANSWOUT falling
edge delay
200
ns
tWKUPW
PANSWOUT active pulse width
1
sec
0.5
- 134 -
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
13.0 TIMING WAVEFORMS
13.1 FDC
Write Date
Processor Read Operation
WD
SA0-SA9
TWDD
AEN
CS
TAR
TRA
DACK
TRR
IOR
TDH
Index
TFD
TDF
D0-D7
INDEX
TR
IRQ
TIDX
Processor Write Operation
TIDX
Terminal Count
SA0-SA9
AEN
DACK
TAW
TC
TWA
TTC
TWW
IOW
TWD
Reset
TDW
D0-D7
RESET
TWI
TRST
IRQ
DMA Operation
Drive Seek operation
TAM
DRQ
DIR
TMCY
DACK
TAA
TMA
TDST
TMRW
IOW or
TSTP
TSTD
STEP
IOR
TMW (IOW)
TMR (IOR)
TSC
- 135 -
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
13.2 UART/Parallel
Receiver Timing
SIN
(RECEIVER
STAR
INPUT DATA)
DATA BITS
PARITY
(5-8)
STOP
TSINT
IRQ3 or IRQ4
IOR
(READ RECEIVER
TRINT
BUFFER REGISTER)
Transmitter Timing
SERIAL OUT
STAR
(SOUT)
STAR
DATA
(5-8)
PARITY
THRS
STOP
(1-2)
TSTI
IRQ3 or IRQ4
THR
IOW
(WRITE THR)
THR
TSI
TIR
IOR
(READ TIR)
- 136 -
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
13.2.1 Modem Control Timing
MODEM Control Timing
IOW
(WRITE MCR)
¢x
¢x
¢x
¢x
¡÷
RTS,DTR
CTS,DSR
DCD
IRQ3 or
IRQ4
¢x
¢x
¡÷
¢x
¢x
¢x
¡÷¢x ¡öTRIM
IOR
(READ MSR)
¡÷
¡ö TMWO
¢x
¢x
¢x
¢x
¢
¢x
¢x
¢x
¢x
¡÷ ¢x¡ö TSIM
¢x
¢x
¢x
¢x
¢x
¢x
¢x
¡ö TSIM
¢x
¢x
¢x
¢x
¢x
¢x
¢x ¢x
¢x
¢x
¢x
¢x
RI
Printer Interrupt Timing
ACK
IRQ7
¡÷
¢x
¢x
¢x
¢x
¢x
¡ö TLAD
¡÷
¢x
¢x
¢x
¢x
¢x
- 137 -
¢x
¢x
¢x
¢x
¢x
¢x
¢x
¡÷ ¡öTRIM
¡öTSIM¡÷
¢x
¢x
¢x
¢x
¢x
¢x
¢x
¢x
¢x
¢x
¡öTMWO
¢x
¢x
¢x
¢x
¢x
¢x
¢x
¢x
¢x
¢x
¢x
¢x
¢x
¢x
¢x
¢
¡ö TLID
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
13.3 Parallel Port
13.3.1 Parallel Port Timing
IOW
t1
INIT, STROBE
AUTOFD, SLCTIN
PD<0:7>
ACK
t2
IRQ (SPP)
IRQ
(EPP or ECP)
t3
t4
nFAULT
(ECP)
ERROR
(ECP)
t5
t2
t4
IRQ
- 138 -
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
13.3.2 EPP Data or Address Read Cycle (EPP Version 1.9)
t3
A<0:10>
IOR
t1
t2
t6
t4
t7
SD<0:7>
t8
t5
t9
IOCHRDY
t10
t13
t15
t14
WRITE
t16
t18
t19
t20
t17
PD<0:7>
t21
ADDRSTB
t22
t23 t24
t25
DATASTB
t26
t27
t28
WAIT
- 139 -
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
13.3.3 EPP Data or Address Write Cycle (EPP Version 1.9)
t3
t4
A10-A0
SD<0:7>
t1
IOW
t5
t2
IOCHRDY
t7
t6
t8
t9
t10
t11
t13
WRITE
t12
t14
PD<0:7>
t15
t16
t17
t18
DATAST
ADDRSTB
t19
t21
t20
WAIT
t22
PBDIR
- 140 -
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
13.3.4 EPP Data or Address Read Cycle (EPP Version 1.7)
t3
A<0:10>
IOR
t1
t2
t4
t6
t7
SD<0:7>
t8
t5
t9
IOCHRDY
t10
t13
t15
t14
WRITE
t16
t18
t19
t17
t20
PD<0:7>
t21
ADDRSTB
t22
t23
t25
t24
DATASTB
t26
t28
t27
WAIT
- 141 -
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
13.3.5 EPP Data or Address Write Cycle (EPP Version 1.7)
t3
t4
A10-A0
SD<0:7>
t1
IOW
t7
IOCHRDY
WRITE
t5
t2
t6
t8
t9
t10
t11
t13
t22
t22
PD<0:7>
t15
t16
t17
t18
DATAST
ADDRSTB
t19
t20
WAIT
13.3.6 Parallel Port FIFO Timing
t4
t3
>|
>|
PD<0:7>
t1
nSTROBE
t2
>|
t6
>
t5
>|
>|
BUSY
- 142 -
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
13.3.7 ECP Parallel Port Forward Timing
t3
nAUTOFD
t4
PD<0:7>
t1
t2
t6
t8
nSTROBE
t5
t5
t7
BUSY
13.3.8 ECP Parallel Port Reverse Timing
t2
PD<0:7>
t1
t3
t4
nACK
t5
t5
t6
nAUTOFD
- 143 -
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
13.4 KBC
13.4.1 Write Cycle Timing
A2, CSB
T1
T5
T3
WRB
ACTIVE
T8
T7
D0~D7
DATA IN
T9
GA20
OUTPUT PORT
T17
T18
FAST RESET PULSE RC
FE COMMAND
13.4.2 Read Cycle Timing
A2,CSB
AEN
T2
RDB
T6
T4
ACTIVE
T10
D0-D7
T11
DATA OUT
13.4.3 Send Data to K/B
CLOCK
(KCLK)
T12
SERIAL DATA
(KDAT)
START D0
T14
D1
D2
D3
T13
D4
T16
D5
D6
D7
P
STOP
T19
- 144 -
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
13.4.4 Receive Data from K/B
CLOCK
(KCLK)
T14
T15
SERIAL DATA
(T1)
START
D0
D1
D2
T13
D3
D5
D4
D6
D7
P
STOP
T20
13.4.5 Input Clock
CLOCK
CLOCK
T21
13.4.6 Send Data to Mouse
MCLK
T25
MDAT
START
Bit
T22
D0
D1
T23
T24
D2
D3
D4
D5
D6
D7
P
STOP
Bit
13.4.7 Receive Data from Mouse
MCLK
T29
T26
T27
T28
MDAT
START D0
D1
D2
D3
D4
D5
- 145 -
D6
D7
P
STOP
Bit
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
13.5 GPIO Write Timing Diagram
A0-A15
VALID
IOW
D0-7
VALID
GPIO10-17
GPIO20-25
PREVIOUS STATE
VALID
tWGO
13.6 Master Reset (MR) Timing
Vcc
tVMR
MR
13.7 Keyboard/Mouse Wake-up Timing
KCLK
MCLK
PANSWIN
PANSWOUT
tWKUPW
HI-Z
tWKUPD
tSWL
tSWZ
- 146 -
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
14.0 APPLICATION CIRCUITS
14.1 Parallel Port Extension FDD
JP13
WE2/SLCT
WD2/PE
MOB2/BUSY
DSB2/ACK
PD7
PD6
PD5
DCH2/PD4
RDD2/PD3
STEP2/SLIN
WP2/PD2
DIR2/INIT
TRK02/PD1
HEAD2/ERR
IDX2/PD0
RWC2/AFD
STB
13
25
12
24
11
23
10
22
9
21
8
20
7
19
6
18
5
17
4
16
3
15
2
14
1
JP 13A
DCH2
HEAD2
RDD2
WP2
TRK02
WE2
WD2
STEP2
DIR2
MOB2
DSB2
IDX2
RWC2
34
32
30
28
26
24
22
20
18
16
14
12
10
8
6
4
2
33
31
29
27
25
23
21
19
17
15
13
11
9
7
5
3
1
EXT FDC
PRINTER PORT
Parallel Port Extension FDD Mode Connection Diagram
14.2 Parallel Port Extension 2FDD
JP13
WE2/SLCT
WD2/PE
MOB2/BUSY
DSB2/ACK
DSA2/PD7
MOA2/PD6
PD5
DCH2/PD4
RDD2/PD3
STEP2/SLIN
WP2/PD2
DIR2/INIT
TRK02/PD1
HEAD2/ERR
IDX2/PD0
RWC2/AFD
STB
13
25
12
24
11
23
10
22
9
21
8
20
7
19
6
18
5
17
4
16
3
15
2
14
1
JP 13A
DCH2
HEAD2
RDD2
WP2
TRK02
WE2
WD2
STEP2
DIR2
MOB2
DSA2
DSB2
MOA2
IDX2
RWC2
34
32
30
28
26
24
22
20
18
16
14
12
10
8
6
4
2
33
31
29
27
25
23
21
19
17
15
13
11
9
7
5
3
1
EXT FDC
PRINTER PORT
Parallel Port Extension 2FDD Connection Diagram
- 147 -
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
14.3 Four FDD Mode
74LS139
7407(2)
W83977F
DSA
G1
A1
1Y0
1Y1
DSB
B1
1Y2
1Y3
2Y0
2Y1
2Y2
2Y3
MOA
G2
MOB
A2
DSA
DSB
DSC
DSD
MOA
MOB
MOC
MOD
B2
15.0 ORDERING INFORMATION
PART NO.
W83977TF-P
W83977TF-A
W83977TF-PW
W83977TF-AW
KBC FIRMWARE
REMARKS
TM
Phoenix MultiKey/42
AMIKEY
TM
-2
TM
Phoenix MultiKey/42
AMIKEY
TM
-2
with OnNow / security keyboard wake-up
with OnNow / security keyboard wake-up
16.0 HOW TO READ THE TOP MARKING
Example: The top marking of W83977TF-A
inbond
W83977TF-A
 AM. MEGA. 87-96
730AC2722968SA
1st line: Winbond logo
2nd line: the type number: W83977TF-A
TM
3rd line: the source of KBC F/W -- American Megatrends Incorporated
4th line: the tracking code
730 A C 2 722968 SA
730: packages made in '97, week 30
A: assembly house ID; A means ASE, S means SPIL.... etc.
C: IC revision; B means version B, C means version C
2: wafers manufactured in Winbond FAB 2
722968: wafer production series lot number
SA: if made by 0.5-um process: SA; otherwise by 0.6-um process: blank
- 148 -
Publication Release Date: March 1998
Revision 0.62
W83977TF
PRELIMINARY
17.0 PACKAGE DIMENSIONS
(128-pin PQFP)
HE
A1
A2
b
c
D
E
e
HD
HE
L
L1
y
0
65
64
103
D
HD
39
128
e
38
b
c
Nom
Max
0.35
0.45
0.010
0.014
0.018
2.57
2.72
2.87
0.101
0.107
0.113
0.10
0.20
0.30
0.004
0.008
0.012
A
A1
y
Nom
Max
Min
0.10
0.15
0.20
0.004
0.006
0.008
13.90
14.00
14.10
0.547
0.551
0.555
19.90
20.00
20.10
0.783
0.787
0.791
0.50
0.020
17.00
17.20
17.40
0.669
0.677
23.00
23.20
23.40
0.905
0.913
0.921
0.65
0.80
0.95
0.025
0.031
0.037
0.063
1.60
0.08
0
0.685
7
0.003
0
7
Note:
1.Dimension D & E do not include interlead
flash.
2.Dimension b does not include dambar
protrusion/intrusion .
3.Controlling dimension : Millimeter
4.General appearance spec. should be based
on final visual inspection spec.
A2
See Detail F
Seating Plane
Dimension in inch
0.25
Min
102
1
Dimension in mm
Symbol
E
L
L1
Detail F
5. PCB layout please use the "mm".
Headquarters
Winbond Electronics (H.K.) Ltd.
No. 4, Creation Rd. III
Science-Based Industrial Park
Hsinchu, Taiwan
TEL: 886-35-770066
FAX: 886-35-789467
www: http://www.winbond.com.tw/
Rm. 803, World Trade Square, Tower II
123 Hoi Bun Rd., Kwun Tong
Kowloon, Hong Kong
TEL: 852-27516023-7
FAX: 852-27552064
Winbond Electronics
(North America) Corp.
2730 Orchard Parkway
San Jose, CA 95134 U.S.A.
TEL: 1-408-9436666
FAX: 1-408-9436668
Taipei Office
11F, No. 115, Sec. 3, Min-Sheng East Rd.
Taipei, Taiwan
TEL: 886-2-7190505
FAX: 886-2-7197502
TLX: 16485 WINTPE
Please note that all data and specifications are subject to change without notice. All the
trade marks of products and companies mentioned in this data sheet belong to their
original owners.
- 149 -
Publication Release Date: March 1998
Revision 0.62