ETC MX98746

PRELIMINARY
MX98745
100 BASE-TX/FX
REPEATER CONTROLLER
1.0 FEATURES
• IEEE 802.3u D5 repeater and management compatible
• Support 7 TX/FX ports and 1 universal port (TX or MII
port selectable)
• Support 8-scale utilization and collision rate LED display
• Asynchronous Expansion port clock supported for
easily stackable application
• Separate jabber and partition state machines for each
port
• On-chip elasticity buffer for PHY signal re-timing to the
MX98745 clock source
• Contents of internal register loaded from EEPROM
• PCS/MAC type MII interface selectable
• CMOS device features high integration and low power
with a signle +5V supply
2.0 GENERAL DESCRIPTION
The MX98745, Second generation 100 Mb/s TX/FX Hub
Controller (XRC II), is designed specifically to meet the
needs of today's high speed Fast Ethernet networking
systems. The MX98745 is fully IEEE 802.3u D5 clause
27 repeater compatible.
Difference from MX98741, which provides 8 dedicated
TX/FX ports and 3 MII ports, MX98745 support 7 dedicated TX/FX ports and one programmble TX/FX/MII port.
Whenever MII port is programmed, MX98745 also supports the flexibility to make user can easily select PCS or
MAC type MII for system application. With this programmable MII interface, user can easily connect MX98745 to
MX98742 (Bridge), or T4 transceiver. Or user can use
this programmable MII interface to connect to either MAC
or PCS type data transceiver.
P/N:PM0427
All contents of internal registers are loaded from
EEPROM in MX98745. If system application prefers
default setting instead of using contents from EEPROM,
EEPROM operation can be disabled by setting EECONF
to low. This feature faciliates system modulization application.
8 scale of utilization LED is also provided by MX98745.
They are 1%, 3%, 5%, 10%, 20%, 40%, 60% and 80+%.
The defination for utiliztion is Mbs Received/100 Mb within
one second sampling period. Meanwhile, RX/LINK, Partition, Isolation and Collision status are also provided
through LED display.
A great improvement in MX98745 (compared to
MX98741) is that it also provides "synchronous expansion port data transfer mode" to make stackable design
more easier.
REV. 1.4, JUL. 8, 1998
1
MX98745
3.0 BLOCK DIAGRAMS
MDC
MDIO
LSCLK
SIGDET[7:0]
Jabber Clock Generator
RESEL
Port 0 5B RX/
Port 0 4B RX
RDAT0[4:0]
Port 0 5B RX/
Port 0 4B RX
TDAT0[4:0]
RSCLK0
SCRCTRL
Repeater Core
&
Control/Status
Registers
TXCLK
(MII Only)
RDAT7[4:0]
Port 7 RX
Relative FUN
RSCLK7
Port 7
Relative FUN
TDAT7[4:0]
Utilization/ Status LED
Display FUN
Expansion Port Function
EDACT JAMI EDAT[4:0] EPCLK JAMO EDENL EDCRS ANYACT LED[8:0]
LDSEL[2:0]
Figure 3-1 Block Diagram forMX98745
P/N:PM0427
REV. 1.4, JUL. 8, 1998
2
MX98745
4.0 PIN CONFIGURATION
GND
RDAT30
RDAT31
RDAT32
RDAT33
RDAT34
GND
TDAT30
TDAT31
TDAT32
TDAT33
TDAT34
GND
RSCLK4
SIGDET4
VDD
RDAT40
RDAT41
RDAT42
RDAT43
RDAT44
TDAT40
TDAT41
TDAT42
TDAT43
TDAT44
GND
RSCLK5
SIGDET5
RDAT50
RDAT51
RDAT52
RDAT53
RDAT54
TDAT50
TDAT51
TDAT52
TDAT53
TDAT54
GND
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
GND
RSCLK6
SIGDET6
RDAT60
RDAT61
RDAT62
RDAT63
RDAT64
TDAT60
TDAT61
TDAT62
TDAT63
TDAT64
GND
RSCLK7
SIGDET7
GND
RDAT70
RDAT71
RDAT72
RDAT73
RDAT74
VDD
TDAT70
TDAT71
TDAT72
TDAT73
TDAT74
VDD
LSCLK
IBMON
TSEL
TEST
XCOLED
SCRCTRL
RESETL
COL
MDO
MDIO
VDD
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
MX98745
120
119
118
117
116
115
114
113
112
111
110
109
108
107
106
105
104
103
102
101
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
VDD
SIGDET3
RSCLK3
TDAT24
TDAT23
TDAT22
TDAT21
TDAT20
VDD
RDAT24
RDAT23
RDAT22
RDAT21
RDAT20
GND
SIGDET2
RSCLK2
VDD
TDAT14
TDAT13
TDAT12
TDAT11
TDAT10
GND
RDAT14
RDAT13
RDAT12
RDAT11
RDAT10
SIGDET1
RSCLK1
MON
LED7/PHY4
LED6/PHY3
LED5/PHY2
LED4/PHY1
LED3/PHY0
LED2/TXMII
LED1/PMSEL
GND
80
79
78
77
76
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
VDD
LED0/EECLK/PARSEL
LDS2/ED0
GND
LDS1/EDI
LSD0/EECONF
LEDEN
VDD
EECS
EDACT
ANYACT
GND
EDENL
EDCRS
JAM1
JAM0
EPCLK
EDAT4
EDAT3
EDAT2
EDAT1
EDAT0
GND
TXEN
CRS
GND
TXCLK
TDAT04/TXER
TDAT03/TXD3
TDAT02/TXD2
TDAT01/TXD1
TDAT00/TXD0
EDAT04/RXER
RDAT03/RXD3
RDAT02/RXD2
RDAT01/RXD1
RDAT00/RXD0
SIGDET0/RXDV
RSCLK0
VDD
Figure 4-1 Pin Configuration for XRCII
P/N:PM0427
REV. 1.4, JUL. 8, 1998
3
MX98745
5.0 PIN DESCRIPTION
A. MX Data Transceiver (Am78965/Am78966 or MC68836), 98 pins
PAD #
24-28
9-13
155-159
142-146
128-132
113-117
98-102
30
Name
TDAT[7:1][0:4]
I/O
O,
TTL
Description
Transmit Data. These five outputs are 5B encoded transmit data sym
bols, driven at the rising edge of LSCLK.
TDAT4 is the Most Significant Bit.
LSCLK
I,
TTL
18-22
4-8
150-154
137-141
122-126
107-111
92-96
15,2
148,134
118,104
90,42
16,3,
149,135,
119,105,
91
31
RDAT[7:1][0:4]
I,
TTL
Local Synchrnous Clock. This pin supplies the frequency reference to
the MX98745 within same HUB. It should be driven by a crystalcontrolled 25M clock source.
Receive Data. These 5 bit parallel data symbol from transceiver are
latched by the rising edge of RSCLK of each port.
RDAT4 is the Most Significant Bit.
RSCLK[7:0]
I,
TTL
Recovered Symbol Clock. This is a 25 MHz clock, which is derived
from the clock synchronization PLL circuit.
SIGDET[7:1]
I,
TTL
Signal Detect. This signal indicates that the received signal is above
the detection threshold and will be used for the link test state machine.
Monitor
I,
TTL
Monitor Mode. Internal Pulldown. When this pin is set to one, LED
display pins LED[9:0] will be changed to monitor mode.
Table 5-1 Pin Description for XRCII
P/N:PM0427
REV. 1.4, JUL. 8, 1998
4
MX98745
B. Expansion Port, 12 pins
PAD #
65
Name
JAMO
I/O
O,
CMOS
66
JAMI
I,
TTL
68
EDENL
I,
Sche
63-59
EDAT[4:0]
64
EPCLK
I/O,
TTL
I/O,
TTL
70
ANYACT
67
EDCRS
71
EDACT
O,
CMOS
I,
Sche
O,
CMOS
Description
Forced Jam Out. Active High. The OR’d forced jam signals controlled by
Carrier Integrity Monitor of each port. If collision occurs inside the XRC II
(exclude JAMI), this pin is also asserted.
Forced Jam Input. Active High. Asserted by external arbitor, and XRCII will
generate JAM patterns to all its ports whenever this signal is validate more
than 40 ns. This signal is filtered by LSCLK for 40ns internally.
Enable Expansion Data. Active Low. Asserted by an external arbitor. XRC II
will not drive data onto EDAT until this pin is asserted. Assertion time less
than 40ns will not be recognized by XRC II.
Expansion Data. Bidirectional 5 bit-wide data. By default, EDAT is an input.
An external arbitor coordinates multiple devices on EDAT.
Expansion port Data Clock. This clock will be outputed by XRCII along with
the EDAT[4:0]. Another module of XRCII should use this signal as expansion
port data input clock.
Any Activity. Active High. When XRCII tries to release data onto EDAT, this
pin will be asserted by XRC II.
Expansion Data Carrier Sense. When this pin is asserted, XRC II will
recognize that there is activity on expansion port data bus EDAT and perform
corresponding activity within XRCII itself.
Expansion Data Activity. When XRCII detects that EDENL is asserted by
external arbitor, it will assert EDACT high. System application can use this
signal to control the data bus flow of EDAT.
Table 5-1 Pin Description for XRC II (Continued)
P/N:PM0427
REV. 1.4, JUL. 8, 1998
5
MX98745
C. Universal Port (UP), 14 pins
PAD # Name
43
SIGDET0/
RXDV
I/O
I,
TTL
44-47
RDAT0[0:3]/
RXD[0:3]
I,
TTL
48
RDAT04/
RXER
I,
TTL
56
CRS
I/O,
TTL
57
TXEN
49-52
TDAT[0:3]/
TXD[0:3]
O,
CMOS
O,
CMOS
53
TDAT04/
TXER
O,
CMOS
37
COL
I/O,
CMOS
54
TXCLK
I/O,
CMOS
Description
Signal Detect/Receive Data Valid. When TXMII (pin 84) is detected high
during power on reset, This pin works as Signal detect in 5B data mode. When
TXMII is low, this pin is output and works as RXDV in MII mode. This signal
remains asserted through the whole frame, starting with the start-of-frame
delimiter and excluding any end-of-frame deliminter
Receive Data[3:0]. No matter TXMII’s value is, these four pins work as the
receive data both in TX mode and MII mode. Receive data is synchronous to
RSCLK0's rising edge.
Receive Data Bit 4/Receive Data Error. When TXMII is detected as 1, this pin
works as the MSB of RDAT0[4:0]. When MII mode is selected, this pin is
RXER and synchronous to RSCLK0's rising edge.
Carrier Sense. In PCS Mode, synchronous to TXCLK. This pin is asserted
when (1) the receiving medium is not idle, or (2) the transmitting medium is not
idle in the half-duplex mode. In MAC mode (PMSEL is low), this pin is input.
Transmit Enable. This pin is output and synchronous to the TXCLK's rising
edge whenever valid data is presented on TXD[3:0]
Transmit Data. No matter TXMII’s value is, these four pins work as the
transmit data both in TX mode and MII mode. In TX mode, TDAT is
synchronous to LSCLK rising edge. In MII mode, TXD[0:3] is synchronous to
TXCLK rising edge.
Transmit Data Bit 4/Transmit ERROR. When TXMII is set to one, this pin work
as the MSB of TDAT of port 0. When TXMII is low, This pin acts as TXEN and
is synchronous to the TXCLK's rising edge. When TXER is asserted for one or
more than one TXCLK period while TXEN is also asserted, one or more"HALT ”
symbols will present at TXD[3:0].
Collision. This signal is asserted if both the receiving media and TXEN are
active. When PCS type MII is selected, this pin is output from XRCII and
indicates that there is collision within the XRCII. When PMSEL is 0, COL is
input to XRCII and indicates that there is collision on the receiving port.
Transmit Clock. 25M Hz clock. TXD[3:0], TXEN, TXER are synchronous to
this clock's rising edge. In PCS type MII (PMSEL is 1), CRS and COL are also
synchronous to this clock's rising edge.
Table 5-1 Pin Description for XRCII (Continued)
P/N:PM0427
REV. 1.4, JUL. 8, 1998
6
MX98745
D. Management, 2 pins
PAD #
38
Name
MDC
39
MDIO
I/O
I,
TTL
I/O,
TTL
Description
Management Data Clock. The timing reference for MDIO.
The minumum high and low times are 200 ns each.
Management Data Input/Output. A bi-directional signal.
The selection of input/output direction is based on IEEE802.3u management
functions (Section 22.2.4).
E. Test/Miscellaneous, 5 pins
PAD #
33
Name
TEST
I/O
I
32
TSEL
I
34
XCOLED
35
SCRCTRL
O,
LED
I,
TTL
36
RESETL
31
IBMON
I,
Sche
I,
TTL
Description
Test. Industrial test pin. Set to 0 for normal operation.
When programmed to logic 1, XRC II is in test mode.
Test Select. Used by industrial test. Internal Pulldown.
Set to 0 for normal operation.
Collision LED. Active low. When there is collision within the XRC II, XCOLED
will be on for 80ms and off for 20ms.
Scrambler Control. Active High. When this pin is set to 0. All TX port will be
set to descramble mode, i.e. contents of register #17 will be disabled. When
this pin is set to 1. Each port's scrambler/descrambler is controller by corre
sponding bit in register #17. Internally pullup.
Reset. Active Low. Will be filtered by LSCLK within the MX98745.
Internal Bus Monitor. In house debugging usage. Internally pull down.
Table 5-1 Pin Description for XRC II (Continued)
P/N:PM0427
REV. 1.4, JUL. 8, 1998
7
MX98745
F. LED Display/EEPROM Interface, 14 pins
PAD # Name
74
LEDEN
I/O
O,
78,
76,
75
LDS2/EDO,
LDS1/EDI,
LDS0/EECONF
I/O,
TTL
79
LEDO/,
EECK/,
PARSEL
I/O
TTL
82
LED1/PMSEL
I/O,
TTL
Description
Led Output Enable. When LEDEN is asserted high, it means that varuous
internal CMOS status is shown on LED[7:0] according to the value on
LDS[2:0]
LED Output Select. LDS0 is internally pulldown and value on LDS0 will be
latched internally by MX98745 at the rising edge of RESETL as the value
of EECONF. Value on LDS1 will act as EEPROM Data Input signal during
EEPROM loading operation (after power on reset and EECONF is set to 1)
and LDS2 will be data output from EEPROM.
When EECONF is low, EEPROM operation will be disabled.
After power on reset, LDS[2:0] work as the select pins of LED[7:0] output.
The following are corresponding definition
LDS2 LDS1 LDS0
0
0
1
Link/Receive
0
1
0
Isolation
0
1
1
Partition
1
0
0
Utilization
1
0
1
Collision Rate
LED 0/EEPROM Clock/Partition Select. Value on this pin will be latched by
MX98745 at the rising edge of RESETL as the value of Partition Select
(PARSEL).
When EECONF is set to 1, this pin will work as EEPROM clock pin and
output by MX98745 after power on reset. When EEPROM operation is
enabled, internal repeater function will be disabled until contents in EEPROM
is loaded into MX98745.
After EEPROM operation is completed, this pin will display port 0's
Receivee/Link, Partition, Isolation status and indicates 10% Network
utilization and 3% collision rate according to the value of LDS[2:0].
LED 1/PCS & MAC type MII Select. When Power on reset, value on this
pin will be latched at the rising edge of RESETL and be the value of PMSEL
which can program the universal port (port 0) to PCS or MAC type MII
interface. In normal operation (after power on reset), this pin will display
port 1's Receivee/Link, Partition, Isolation status and indicates 20%
Network utilization and 6% collision rate according to the value on LDS[2:0]
Table 5-1 Pin Description for XRC II (Continued)
P/N:PM0427
REV. 1.4, JUL. 8, 1998
8
MX98745
F. LED Display (Continued)
PAD #
83
Name
LED2/
TXMII
I/O
I/O,
TTL
84
LED3/
PHY0
I/O,
TTL
85
LED4/
PHY1
I/O,
TTL
86
LED5/
PHY2
I/O,
TTL
87
LED6/
PHY3
I/O,
TTL
Description
LED 2/Port0 TX/MII mode Select. When Power on reset, value on this pin
will be latched at the rising edge of RESETL and be the value of TXMII which
can program the universal port (port 0) to TX mode (5B interface) or MII mode
(4B) interface. When TXMII is set to 1, Port 0 of XRC II will be programmed to
TX mode and PMSEL will be disabled. In normal operation (after power on
reset), this pin will display port 2's Receivee/Link, Partition, Isolation status
and indicates 30% Network utilization and 9% collision rate according to the
value on LDS[2:0]
LED 3/Physical Address 0. Value on LED3 will be latched at the rising edge of
RESET as the setting of Device physical address 0. If EECONF is set to 1,
PHY0 will be overwritten by the contents of EEPROM.
After EEPROM operation is completed (in case EECONF is set to 1), this pin
will display port 3's Receivee/Link, Partition, Isolation status and indicates 10%
Network utilization and 8% collision rate according to the value on LDS[2:0]
LED 4/Physical Address 1. Value on LED4 will be latched at the rising edge of
RESETL as the physical address 1 of MX98745. If EECONF is set, Physical
address will be overwritten by the value from EEPROM.
After EEPROM operation is completed, this pin will display port 4's Receivee/
Link, Partition, Isolation status and indicates 20% Network utilization and 10%
collision rate according to the value on LDS[2:0].
LED 5/Physical Address 2. Value on LED5 will be latched at the rising edge of
RESETL as the physical address 2 of MX98745. If EECONF is set, Physical
address will be overwritten by the value from EEPROM.
After EEPROM operation is completed, this pin will display port 5's Receivee/
Link, Partition, Isolation status and indicates 40% Network utilization and 13%
collision rate according to the value on LDS[2:0].
LED 6/Physical Address 3. Value on LED6 will be latched at the rising edge of
RESETL as the physical address 3 of MX98745. If EECONF is set, Physical
address will be overwritten by the value from EEPROM.
After EEPROM operation is completed, this pin will display port 6's Receivee/
Link, Partition, Isolation status and indicates 60% Network utilization and 15%
collision rate according to the value on LDS[2:0].
Table 5-1 Pin Description for XRC II (Continued)
P/N:PM0427
REV. 1.4, JUL. 8, 1998
9
MX98745
F. LED Display (Continued)
PAD #
88
Name
LED7/
PHY4
I/O
I/O,
TTL
72
EECS
89
MON
O,
CMOS
I/O,
TTL
Description
LED 7/Physical Address 4. Value on LED7 will be latched at the rising edge of
RESETL as the physical address 4 of MX98745. If EECONF is set, Physical
address will be overwritten by the value from EEPROM.
After EEPROM operation is completed, this pin will display port 7's Receivee/
Link, Partition, Isolation status and indicates 80+% Network utilization and 20+%
collision rate according to the value on LDS[2:0].
EEPROM Chip Select. Output by MX98745 when EECONF is set and EEPROM
operation is activated by MX98745.
Monitor. Value on this pin will be latched at the rising edge of RESETL. When
programmed to high, internal state machines's states will be outputed to this
pin serially for debugging usage. For normal operation, left unconnected.
G. Power/Ground Pins
PAD #
1,14,
17,55,
58,69,
77,81,
97,106,
121,127,
133,147,
160
23,29,
41,73,
80,103,
112,120,
Name
GND
VDD
I/O
Description
Ground.
5V Power Supply.
136,
Table 5-1 Pin Description for XRC II (Continued)
P/N:PM0427
REV. 1.4, JUL. 8, 1998
10
MX98745
6.0 FUNCTIONAL AND OPERATION DESCRIPTION
6.1 All TX MODE SELECTED
EEPROM
Arb
XRC
XRC
DT&
PMD
DT&
PMD
DT&
PMD
DT&
PMD
Port 0
Port 7
Port 8
Port 15
Figure 6-1 Pure TX Mode operation for XRC II
6.2 TX AND MII MIXED MODE
Arbitor
EEPROM
XRC
MII
or
FX
XRC
DT&
PMD
DT&
PMD
DT&
PMD
Port 7
Port 8
Port 15
Figure 6-2 TX/MII Mixed Mode operation for XRC II
P/N:PM0427
REV. 1.4, JUL. 8, 1998
11
MX98745
6.3 INTERNAL REGISTERS
All the registers can be accessed through MII's MDC and
MDIO. Although XRC II connects to multiple 100-TX
PHY's, they are all identical. Each XRC has only one
PHY address as defined by PHY[4:0] pins (which will be
latched by the rising edge of RESETL, and will be overwritten by the contents of EEPROM whenever EECONF
is set to 1). If multiple XRC's are on the same MDIO bus,
each of them should have different PHY address. Other
non-XRC PHY devices (e.g. T4) are also allowed to be
managed with the same management interface as long
as PHY address of each device is distinct.
reset control register (#16), Port Scremabler control register (#17), Port Enable Control Register (#18), Isolation
Disable Control Register (#19) and Partition Disable Control Register (#20).
Port Status Registers are located from address #25 to
address #29. These registers include Link Status Register (#25), Partition Status Register (#26), Elastic Buffer
Status Register (#27), Jabber Status Register (#28) and
Isolation Status Register (#29).
Register #31 is Configuration Register. Value latched at
the rising edge of RESETL will be stored in this register.
Value on this register will be overwritten by contents of
EEPROM in case EECONF is set to 1 except PMSEL
and TXMII which will be affected only by hardwire setting.
Register 0 and 1 are Command and Status registers
which specified in [1]. Additional registers provided by
MX98745 is located from address 16 to 31 (decimal
value). Port Control Registers are located from address
#16 to address #20. These control registers include port
A. Command Register (register #0) (R/W)
Bit(s)
0.15
Name
Reset
0.14
Loop Back
0.13
Speed Selection
0.12
Auto-Negotiation Enable
0.11
Power Down
0.10
Isolate
Description
1 : PHY reset. A 240ns reset pulse will be generated to
reset XRC internal logic.
0 : normal operation.
1 : enable loopback mode.
0 : disable loopback mode.
The default setting is 0.
Forced to 1 and indicate 100 Mb/s.
Write 0 to this bit has no effect.
Forced to 0 and indicate that Auto-Negotiation process
is disable.
Write 1 to this bit has no effect.
1 : power down. COCLK and TXCLK for each port will be
disabled. Clock for Management Block will keep running.
During Power down, all state machines will be reset to its
default state.
0 : normal operation.
1 : electrically Isolate PHY from MII
0 : normal operation
P/N:PM0427
R/W
R/W
SC
R/W
R
R
R/W
R/W
R/W
REV. 1.4, JUL. 8, 1998
12
MX98745
Bit(s)
0.9
Name
Restart
Auto-Negotiation
0.8
Duplex Mode
0.7
Collision Test
0.6:0
Reserved
Description
R/W
Forced to 0 and indicate that Auto-Negotiation process is
R
disable.
Write 1 to this bit has no effect.
Forced to 0 and indicate that only Half
R
Duplex is available.
Write 1 to this bit has no effect.
1 : enable COL signal test. The PHY will assert the COL
R/W
signal within 5120 ns in response to the assertion of TXEN.
While this bit is set to one, the PHY will deassert the COL
signal within 40 ns in respons to the deassertion of TXEN.
0 : normal operation.
Set to 0 after power on reset.
Value 0 will be read when one tries to read these bits.
R
Table 6-1 Control Register Bit Definition
B. Status Register (register #1) (R)
Bit(s)
1.15
Name
100BASE-T4
1.14
1.12
100BASE-X
Full Duplex
100BASE-X
Half Duplex
10 Mb/s Full Duplex
1.11
10 Mb/s Half Duplex
1.10:6
1.5
Reserved
Auto-Negotiation
1.4
1.3
1.2
Remote Fault
Auto-Negotiation
Ability
Link Status
1.1
Jabber Detect
1.0
Extended Capability
1.13
Description
Forced to 0 and indicates that XRC is not able to perform
100BASE-T4.
Forced to 0 and indicates that XRC is not able to perform
100BASE-X Fill Duplex.
Forced to 1 and indicates that XRC is able to perform
100BASE-X Half Duplex.
Forced to 0 and indicates that XRC is not able to perform
10 Mb/s Full Duplex.
Forced to 0 and indicates that XRC is not able to perform
10 Mb/s Half Duplex.
Value 0 will be released by XRC when read.
Forced to 0.
Complete
Forced to 0.
Forced to 0.
R/W
R
R
R
R
R
R
R
R
R
1 : All ports are link up.
R
0 : Any port is link fail. Will be set to 1 after this port is read.
1 : Jabber condition in any port is detected.
R
0 : No Jabber condition detected for all ports
Forced to 1.
R
Table 6-2 Status Register Bit Definition
P/N:PM0427
REV. 1.4, JUL. 8, 1998
13
MX98745
C. Port Reset Register (register #16) (R/W)
Bit(s)
16.15:8
16.7
Name
Reserved
ResetP7
16.6
ResetP6
16.5
ResetP5
16.4
ResetP4
16.3
ResetP3
16.2
ResetP2
16.1
ResetP1
16.0
ResetP0
Description
Ignored when read.
1 : reset Port 7's Logic.
0 : not reset Port 7's Logic.
Power on low.
1 : reset Port 6's Logic.
0 : not reset Port 6's Logic.
Power on low.
1 : reset Port 5's Logic.
0 : not reset Port 5's Logic.
Power on low.
1 : reset Port 4's Logic.
0 : not reset Port 4's Logic.
Power on low.
1 : reset Port 3's Logic.
0 : not reset Port 3's Logic.
Power on low.
1 : reset Port 2's Logic.
0 : not reset Port 2's Logic.
Power on low.
1 : reset Port 1's Logic.
0 : not reset Port 1's Logic.
Power on low.
1 : reset Port 0's Logic.
0 : not reset Port 0's Logic.
Power on low.
R/W
R
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Table 6-3 Port Reset Register Bit Definition
Each bit will not clear to 0 automatically whenever it is
set to 1. To ensure the MX98745 works properly, one
should write 0 back to Port reset register after written 1
to corresponding bit.
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REV. 1.4, JUL. 8, 1998
14
MX98745
D. Scrambler Control Register (register #17) (R/W)
Bit(s)
17.15:8
Name
Reserved
17.7
ScrenP7
17.6
ScrenP6
17.5
ScrenP5
17.4
ScrenP4
17.3
ScrenP3
17.2
ScrenP2
17.1
ScrenP1
17.0
ScrenP0
Description
Write any value to these bits have no effect.
Written value will be released onto MDIO
whenever Read Command is issued
1 : Enable Scrambler/Descrambler at Port 7
0 : Disable Scrambler/Descrambler at Port 7
The default value after power on is 1.
1 : Enable Scrambler/Descrambler at Port 6
0 : Disable Scrambler/Descrambler at Port 6
The default value after power on is 1.
1 : Enable Scrambler/Descrambler at Port 5
0 : Disable Scrambler/Descrambler at Port 5
The default value after power on is 1.
1 : Enable Scrambler/Descrambler at Port 4
0 : Disable Scrambler/Descrambler at Port 4
The default value after power on is 1.
1 : Enable Scrambler/Descrambler at Port 3
0 : Disable Scrambler/Descrambler at Port 3
The default value after power on is 1.
1 : Enable Scrambler/Descrambler at Port 2
0 : Disable Scrambler/Descrambler at Port 2
The default value after power on is 1.
1 : Enable Scrambler/Descrambler at Port 1
0 : Disable Scrambler/Descrambler at Port 1
The default value after power on is 1.
1 : Enable Scrambler/Descrambler at Port 0
0 : Disable Scrambler/Descrambler at Port 0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
The default value after power on is 1.
Table 6-4 Scrambler Control Register Bit Definition
Note : When SCRCTRL is set to 0, contents of this register will be disabled.
P/N:PM0427
REV. 1.4, JUL. 8, 1998
15
MX98745
E. Port Enable Control Register (register #18) (R/W) (Continued)
Bit(s)
18.15:8
Name
Reserved
18.7
EnP7
18.6
EnP6
18.5
EnP5
18.4
EnP4
18.3
EnP3
18.2
EnP2
18.1
EnP1
18.0
EnP0
Description
Write any value to these bits have no effect.
Written value will be released onto MDIO
whenever Read Command is issued
1 : Enable RX/TX functions at Port 7.
0 : Disable RX/TX functions at Port 7.
The default value after power on is 1.
1 : Enable RX/TX functions at Port 6.
0 : Disable RX/TX functions at Port 6.
The default value after power on is 1.
1 : Enable RX/TX functions at Port 5.
0 : Disable RX/TX functions at Port 5.
The default value after power on is 1.
1 : Enable RX/TX functions at Port 4.
0 : Disable RX/TX functions at Port 4.
The default value after power on is 1.
1 : Enable RX/TX functions at Port 3.
0 : Disable RX/TX functions at Port 3.
The default value after power on is 1.
1 : Enable RX/TX functions at Port 2.
0 : Disable RX/TX functions at Port 2.
The default value after power on is 1.
1 : Enable RX/TX functions at Port 1.
0 : Disable RX/TX functions at Port 1.
The default value after power on is 1.
1 : Enable RX/TX functions at Port 0.
0 : Disable RX/TX functions at Port 0.
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
The default value after power on is 1.
Table 6-5 Port Enable Control Register Bit Definition
P/N:PM0427
REV. 1.4, JUL. 8, 1998
16
MX98745
F. Isolation Disable Register (register #19) (R/W)
Bit(s)
19.15:8
Name
Reserved
19.7
ISODIS7
19.6
ISODIS6
19.5
ISODIS5
19.4
ISODIS4
19.3
ISODIS3
19.2
ISODIS2
19.1
ISODIS1
19.0
ISODIS0
Description
Write any value to these bits have no effect.
Written value will be released onto MDIO
whenever Read Command is issued
1 : Port 7 Isolation function is disabled
0 : Port 7 Isolation function is not disabled.
The default value is 0 after reset.
1 : Port 6 Isolation function is disabled
0 : Port 6 Isolation function is not disabled.
The default value is 0 after reset.
1 : Port 5 Isolation function is disabled
0 : Port 5 Isolation function is not disabled.
The default value is 0 after reset.
1 : Port 4 Isolation function is disabled
0 : Port 4 Isolation function is not disabled.
The default value is 0 after reset.
1 : Port 3 Isolation function is disabled
0 : Port 3 Isolation function is not disabled.
The default value is 0 after reset.
1 : Port 2 Isolation function is disabled
0 : Port 2 Isolation function is not disabled.
The default value is 0 after reset.
1 : Port 1 Isolation function is disabled
0 : Port 1 Isolation function is not disabled.
The default value is 0 after reset.
1 : Port 0 Isolation function is disabled
0 : Port 0 Isolation function is not disabled.
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
The default value is 0 after reset.
Table 6-6 Isolation Disable Register Bit Definition
P/N:PM0427
REV. 1.4, JUL. 8, 1998
17
MX98745
G. Partition Disable Register (register #20) (R/W)
Bit(s)
20.15:8
Name
Reserved
20.7
PTNDIS7
20.6
PTNDIS6
20.5
PTNDIS5
20.4
PTNDIS4
20.3
PTNDIS3
20.2
PTNDIS2
20.1
PTNDIS1
20.0
PTNDIS0
Description
Write any value to these bits have no effect.
Written value will be released onto MDIO
whenever Read Command is issued
1 : Port 7 Parition function is disbled.
0 : Port 7 Partition function is not disabled.
The default value is 0 after reset.
1 : Port 6 Parition function is disbled.
0 : Port 6 Partition function is not disabled.
The default value is 0 after reset.
1 : Port 5 Parition function is disbled.
0 : Port 5 Partition function is not disabled.
The default value is 0 after reset.
1 : Port 4 Parition function is disbled.
0 : Port 4 Partition function is not disabled.
The default value is 0 after reset.
1 : Port 3 Parition function is disbled.
0 : Port 3 Partition function is not disabled.
The default value is 0 after reset.
1 : Port 2 Parition function is disbled.
0 : Port 2 Partition function is not disabled.
The default value is 0 after reset.
1 : Port 1 Parition function is disbled.
0 : Port 1 Partition function is not disabled.
The default value is 0 after reset.
1 : Port 0 Parition function is disbled.
0 : Port 0 Partition function is not disabled.
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
The default value is 0 after reset.
Table 6-7 Partition Disable Register Bit Definition (Continued)
P/N:PM0427
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18
MX98745
H. Link Status Register (register #25) (R)
Bit(s)
25.15:8
25.7
Name
Reserved
LinkP7
25.6
LinkP6
25.5
LinkP5
25.4
LinkP4
25.3
LinkP3
25.2
LinkP2
25.1
LinkP1
25.0
LinkP0
Description
Always 0.
1 : Link Status is OK at port 7
0 : Link Status is Fail at Port 7
Status is updated at every LSCLK clock.
1 : Link Status is OK at port 6
0 : Link Status is Fail at Port 6
Status is updated at every LSCLK clock.
1 : Link Status is OK at port 5
0 : Link Status is Fail at Port 5
Status is updated at every LSCLK clock.
1 : Link Status is OK at port 4
0 : Link Status is Fail at Port 4
Status is updated at every LSCLK clock.
1 : Link Status is OK at port 3
0 : Link Status is Fail at Port 3
Status is updated at every LSCLK clock.
1 : Link Status is OK at port 2
0 : Link Status is Fail at Port 2
Status is updated at every LSCLK clock.
1 : Link Status is OK at port 1
0 : Link Status is Fail at Port 1
Status is updated at every LSCLK clock.
1 : Link Status is OK at port 0
0 : Link Status is Fail at Port 0
Status is updated at every LSCLK clock.
R/W
R
R
R
R
R
R
R
R
R
Table 6-8 Link Status Register Bit Definition
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19
MX98745
I. Partition Status Register (register #26) (R)
Bit(s)
26.15:8
26.7
Name
Reserved
PartP7
26.6
PartP6
26.5
PartP5
26.4
PartP4
26.3
PartP3
26.2
PartP2
26.1
PartP1
26.0
PartP0
Description
Always 0.
1 : Port 7 has been partitioned
0 : Port 7 has not been partitioned
Status is updated every 40 ns.
1 : Port 6 has been partitioned
0 : Port 6 has not been partitioned
Status is updated every 40 ns.
1 : Port 5 has been partitioned
0 : Port 5 has not been partitioned
Status is updated every 40 ns.
1 : Port 4 has been partitioned
0 : Port 4 has not been partitioned
Status is updated every 40 ns.
1 : Port 3 has been partitioned
0 : Port 3 has not been partitioned
Status is updated every 40 ns.
1 : Port 2 has been partitioned
0 : Port 2 has not been partitioned
Status is updated every 40 ns.
1 : Port 1 has been partitioned
0 : Port 1 has not been partitioned
Status is updated every 40 ns.
1 : Port 0 has been partitioned
0 : Port 0 has not been partitioned
Status is updated every 40 ns.
R/W
R
R
R
R
R
R
R
R
R
Table 6-9 Partition Status Register Bit Definition
P/N:PM0427
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20
MX98745
J. Elastic Buffer Over/Underflow Status Register (register #27) (R)
Bit(s)
27.15:0
27.7
Name
Reserved
EBOUF7
27.6
EBOUF6
27.5
EBOUF5
27.4
EBOUF4
27.3
EBOUF3
27.2
EBOUF2
27.1
EBOUF1
27.0
EBOUF0
Description
Always 0.
1 : Elastic Buffer Over/Underflow at Port 7
0 : Normal Condition.
Clear to 0 after read.
1 : Elastic Buffer Over/Underflow at Port 6
0 : Normal Condition.
Clear to 0 after read.
1 : Elastic Buffer Over/Underflow at Port 5
0 : Normal Condition.
Clear to 0 after read.
1 : Elastic Buffer Over/Underflow at Port 4
0 : Normal Condition.
Clear to 0 after read.
1 : Elastic Buffer Over/Underflow at Port 3
0 : Normal Condition.
Clear to 0 after read.
1 : Elastic Buffer Over/Underflow at Port 2
0 : Normal Condition.
Clear to 0 after read.
1 : Elastic Buffer Over/Underflow at Port 1
0 : Normal Condition.
Clear to 0 after read.
1 : Elastic Buffer Over/Underflow at Port 0
0 : Normal Condition.
Clear to 0 after read.
R/W
R
R
R
R
R
R
R
R
R
Table 6-10 Elastic Buffer Over/Underflow Status Register Bit Definition
P/N:PM0427
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21
MX98745
K. Jabber Status Register (register #28) (R)
Bit(s)
28.15:0
28.7
Name
Reserved
JABP7
28.6
JABP6
28.5
JABP5
28.4
JABP4
28.3
JABP3
28.2
JABP2
28.1
JABP1
28.0
JABP0
Description
Always 0.
1 : Receive Jabber Active at Port 7
0 : No Jabber condition at Port 7
1 : Receive Jabber Active at Port 6
0 : No Jabber condition at Port 6
1 : Receive Jabber Active at Port 5
0 : No Jabber condition at Port 5
1 : Receive Jabber Active at Port 4
0 : No Jabber condition at Port 4
1 : Receive Jabber Active at Port 3
0 : No Jabber condition at Port 3
1 : Receive Jabber Active at Port 2
0 : No Jabber condition at Port 2
1 : Receive Jabber Active at Port 1
0 : No Jabber condition at Port 1
1 : Receive Jabber Active at Port 0
0 : No Jabber condition at Port 0
R/W
R
R
R
R
R
R
R
R
R
Table 6-11 Jabber Status Register Bit Definition
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22
MX98745
L. Isolation Status Register (register #29) (R)
Bit(s)
29.15:0
29.7
Name
Reserved
ISO7
29.6
ISO6
29.5
ISO5
29.4
ISO4
29.3
ISO3
29.2
ISO2
29.1
ISO1
29.0
ISO0
Description
Always 0.
1 : Port Isolation is occuring at port 7,
0 : Port Isolation is not occuring at port 7.
1 : Port Isolation is occuring at port 6,
0 : Port Isolation is not occuring at port 6.
1 : Port Isolation is occuring at port 5,
0 : Port Isolation is not occuring at port 5.
1 : Port Isolation is occuring at port 4,
0 : Port Isolation is not occuring at port 4.
1 : Port Isolation is occuring at port 3,
0 : Port Isolation is not occuring at port 3.
1 : Port Isolation is occuring at port 2,
0 : Port Isolation is not occuring at port 2.
1 : Port Isolation is occuring at port 1,
0 : Port Isolation is not occuring at port 1.
1 : Port Isolation is occuring at port 0,
0 : Port Isolation is not occuring at port 0.
R/W
R
R
R
R
R
R
R
R
R
Table 6-12 Isolation Status Register Bit Definition
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23
MX98745
M. Configuration Register (register #31) (R/W)
Bit(s)
31.15
31.14
Name
Reserved
L40H80
31.13:12
31.11
Reserved
EECF
31.10
31.9
Reserved
MONITOR
31.8
INTARB
31.7
FLWSPEC
31.6
PXM
31.5
TXXMII
31.4:0
PHY[4:0]
Description
Reserved for further usage.
1:Internal arbiter will qualify EDENL for more than 80 ns.
0:Internal arbiter will qualify EDENL for more than 40 ns.
Power on low.
Reserved for further usage.
Power on reset value of LDS0.
After power on reset, Write 1 to this bit will not make EEPROM operation.
When EECF is low, then value on corresponding pins (known as hardwire
setting) will be latched by MX98745 and overwrite the default setting of
MX98745.
Force to High all the time.
1 : Set XRC II to monitor mode and monitor serial output of internal state
machine through LED7..0
0 : Put MX98745 in normal mode.
0:Internal Arbitor function is disabled.
1:Internal Arbitor function is enabled
Power on low.
1 : Partition function meets IEEE 802.3u i.e. when two ports collide more
than 128 times, two ports will be partitoned by MX98745 simultaneously.
0 : Those ports which Receive after Transmit will be partitioned.(Same as
MX98741) i.e. ports encounter transmit collision will be paritioned only.
Value on LED0 will be stored in this bit in case EECONF is 0.
1:PCS type MII for port0
0:MAC type MII for port0 value on LED1 will be stored at this bit after
power on reset. When TXXMII is set to 1, this bit has no effect.
Contents will not be overwritten by EEPROM.
R/W
R/W
R/W
1 : TX port is programmed (5B) for port 0
0 : MII mode (4B) is programmed for port 0
After power on reset, value on LED2 will be stored on this bit. Contents
will not be overwritten while loading EEPROM.
Physical address of MX98745.
When EECONF is set to 0 (Disabled), value on LED[7:3] will be stored in
these five bits at the rising edge of RESETL.
If EECONF is set to high, value from EEPROM will overwrite the hardwire
setting.
R/W
R
R/W
R
R/W
R/W
R/W
R/W
Table 6-13 Configuration Register Bit Definition
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24
MX98745
6.4 EEPROM Mapping
Word #
5
4
3
2
1
0
Bit 15 .................. 8
MSB of Register #31
MSB of Register #20
MSB of Register #19
MSB of Register #18
MSB of Register #17
MSB of Register #16
7 .......................... 0
LSB of Register #31
LSB of Register #20
LSB of Register #19
LSB of Register #18
LSB of Register #17
LSB of Register #16
7.0 ABSOLUTE MAXIMUM RATINGS
RATING
Supply Voltage (VCC)
DC Input Voltage (Vin)
DC Output Voltage (Vout)
Storage Temperature Range (TSTG)
Power Dissipation (PD)
ESD rating (Rzap = 1.5K, Czap = 100pF)
VALUE
4.75V to 5.25V
-0.5V to VCC+0.5V
-0.5V to VCC+0.5V
-55 C to 150 C
750 mW
2000V
Table 7-1 Absolute Maximum Rating for MX98745
Notice :
Stresses greater than those listed under ABSOLUTE
MAXIMUM RATINGS may cauase permanent damage
to the device. This is a stress rating only and functional
operation of the device at these or any other conditions
above those indicated in the operational sections of this
specification is not implied. Exposure to absolute maximum rating conditions for extended period may affect
reliability.
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25
MX98745
8.0 DC Characteristics
SYMBOL
PARAMETER
A. Supply Current
ICC
Average Active (TXing/
RXing) Supply Current
ICCIDLE
Average Idle Supply Current
IDD
Static IDD Current
B. TTL Inputs, Outputs, Tri-States
Vil
Maximum Low Level
Input Voltage
Vih
Minimum High Level
Input Voltage
Iin
Input Current
Voh
Minimum High Level
Output Voltage
(Others/MII/Expansion)
Vol
Maximum Low Level
Output Voltage
(Others/MII/Expansion)
Ioz
Maximum TRI-STATE
Output Leakage Current
C. CMOS Inputs, Outputs
Voh
Minimum High Level
Output Voltage
Vol
Maximum Low Level
Output Voltage
Vil
Maximum Low Level
Vih
Minimum High Level
Iin
Input Current
CONDITIONS
MIN.
MAX.
UNIT
-
150
mA
-
10
600
mA
uA
-
0.8
V
2.0
-1.0
VCC+0.5
1.0
V
uA
2.4
-
V
-
0.4
V
-10.0
10.0
uA
Ioh = -20uA
VCC-0.1
-
V
Iol = 20uA
Input Voltage
Input Voltage
VI=VCC/GND
-
0.1
0.8
1.0
V
V
V
uA
X1 = 25MHz
VIN = Switching
X1 = 25MHz
VIN=VCC/GND
X1=Undriven
GND = 0V
VI=VCC/GND
Ioh = -2mA/
-4mA/
-8mA
Iol = 2mA/
4mA/
8mA
VOUT=VCC/
GND
2.0
-1.0
Table 8-1 DC Characteristics for MX98745
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26
MX98745
9.0 AC CHARACTERISTICS AND WAVEFORMS
A. Media Independent Interface
T01
T02
T03
MDC
T04
T05
MDIO
Figure 9-1 MDIO Timing Relationship MDC
Symbol
T01
T02
T03
T04
T05a
T05b
Description
Period for MDC
High Time for MDC
Low Time for MDC
MDIO Setup to MDC rising edge (sourced by STA)
MDIO Hold to MDC rising edge (sourced by STA)
MDIO Hold to MDC rising edge (source by XRC)
P/N:PM0427
MIN.
400
160
160
10
10
18
MAX.
25
UNIT
ns
ns
ns
ns
ns
ns
REV. 1.4, JUL. 8, 1998
27
MX98745
T11
T12
T13
RSCLK0
T14
T15
RXD[3:0]
RXDV
RXER
Figure 9-2 Receive Signal Timing Relationships for MII mode
Symbol
T11
T12
T13
T14
T15
Description
RSCLK0 Period (Note 1)
RSCLK0 High Time
RSCLK0 Low Time
RXD[3:0]/RXDV/RXER Setup Time to RSCLK0 rising edge (Note 2)
RXD[3:0]/RXDV/RXER Hold Time to RSCLK0 rising edge (Note 2)
MIN.
40
10
7
10
10
MAX.
40
-
UNIT
ns
ns
ns
ns
ns
Note 1 : The accurate RSCLK frequency shall be 25 MHz
+/- 50 ppm.
Note 2 : The setup time of an MII signal relative to an MII
clock edge is defined as the length of time between when the signal exits and remains out of
the switching region and when the clock enters
the switching region. The hold time of an MII
signal relative to an MII clock edge is defined as
the length of time between when the clock exits
the switching region and when the signal enters
the switching region.
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28
MX98745
T21
T22
T23
TXCLK
T24
T25
TXD[3:0]
TXEN
TXER
Figure 9-3 Trannsmit Signal Timing Relationships at the MII
Symbol
T21
T22
23
T24
T25
Description
TXCLK Period (Note 1)
TXCLK High Time
TXCLK Low Time
TXD[3:0]/TXEN/TXER Setup Time to TXCLK rising edge (Note 2)
TXD[3:0]/TXEN/TXER Hold Time to TXCLK rising edge (Note 2)
MIN.
40
20
18
20
15
MAX.
40
-
UNIT
ns
ns
ns
ns
ns
Note 1 : The accurate TXCLK frequency shall be 25 MHz
+/- 50 ppm. In PCS type MII, this signal is
outputed by MX9745. In MAC type MII, this signal is input to MX98745.
Note 2 : The setup time of an MII signal relative to an MII
clock edge is defined as the length of time between when the signal exits and remains out of
the switching region and when the clock enters
the switching region. The hold time of an MII
signal relative to an MII clock edge is defined as
the length of time between when the clock exits
the switching region and when the signal enters
the switching region. (see section 22.3 in [1])
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29
MX98745
B. Data Transceiver Interface
LSCLK
T31
TDAT[4:0]
Figure 9-4 Trannsmit Signal Timing Relationships at the DT
Symbol
T31
Description
TDAT[4:0] to LSCLK Delay Time
MIN.
10
MAX.
15
UNIT
ns
MAX.
40
-
UNIT
ns
n
ns
ns
ns
Note : Tested under 30pF loading.
T41
T42
T43
RSCLK
T44
T45
RDAT[4:0]
Figure 9-5 Receive Signal Timing Relationships at the DT
Symbol
41
T42
T43
T44
T45
Description
RSCLK Period (Note 1)
RSCLK Pulse Width High
RSCLK Pulse Width Low Time
RDAT[4:0] Valid to RSCLK Rise
RSCLK Rise to RDAT[4:0] Invalid
MIN.
40
11
20
2
4
Note 1 : The accurate RSCLK frequency shall be 25 MHz +/- 50 ppm.
P/N:PM0427
REV. 1.4, JUL. 8, 1998
30
MX98745
T51
RESETL
Figure 9-6 Timing Constraint RESEL
Symbol
T51
Description
Pulse Width for RESETL
MIN.
800
MAX.
-
UNIT
us
Note : RESETL must keep active low until LSCLK is stable more than 200 us.
C. Expansion Port Interface
LSCLK
ANYACT
T71
EDENL
T72
T73
EDACT
Figure 9-7 Expansion Port with One port activates
Symbol
T71
T72
T73
Description
ANYACT asserted to EDENL asserted (Note 3)
LSCLK rising to EDACT asserted (Note 1, 2)
LSCLK rising to EDACT deassert
MIN.
MAX.
80
20
20
UNIT
ns
ns
ns
Note 1 : EDENL will be filtered by 2 LSCLK clock within
MX98745. Whenever MX98745 detects EDENL,
it will assert EDACT at the rising edge of LSCLK
Note 2 : Expansion port data will be released onto
EDAT[4:0] at the next LSCLK rising edge right
after EDACT is asserted which is not shown in
this figure.
Note 3 : ANYACT has not any timing relationship to LSCLK
in MX98745. i.e. it is asynchronous to LSCLK.
P/N:PM0427
REV. 1.4, JUL. 8, 1998
31
MX98745
LSCLK
ANYACT1
ANYACT2
EDENL1
T81
EDENL2
EDACT1
T82
JAMI
T83
JAMO1
Figure 9-8 Expansion Port with Collision (Note 1)
Symbol
T81
T82
T83
Description
Valid EDENL duration to make EDACT active
Collision Condition to JAMI asserted (Note 2)
JAMO asserted to JAMI asserted (Note 3)
MIN.
80
MAX.
10
10
UNIT
ns
ns
ns
Note 1 : EDENL2 asserted after collision will not make
EDACT2 assert in MX98745 due to MX98745
will mask activity from expansion port from ces
sation of collision to cessation of ANYACT2.
Note 2 : Deassert timing is the same
Note 3 : Deassert timing is the same. Either T72 or T73
should cause JAMI assert
Note 4 : EDENL, JAMI and EDCRS (not shown in this
timing) should be filtered by LSCLK to resolve
asynchronous issue.
P/N:PM0427
REV. 1.4, JUL. 8, 1998
32
MX98745
EPCLK
T91
/I/
EDAT
/J/
T92
/K/
/D1/
T93
/T/
/R/
Figure 9-9 EPCLK and EDAT Timing Relationship
Symbol
T91
T92
T93
Description
EPCLK to EDAT delay time
(EPCLK and EDAT outputed from MX98745)
EDAT Setup Time (Input to MX98745)
EDAT Hold Time (Input to MX98745)
MIN.
MAX.
UNIT
12
5
5
16
-
ns
ns
ns
MIN.
9.9
4.0
4.9
4.0
4.9
MAX.
10.1
-
UNIT
ms
ms
ms
ms
ms
D. LED Display
T96
LEDEN
T97
T98
T99
T100
LDS2_0
LED7_0
Figure 9-10 Timing Relationship for LED Display
Symbol
T96
T97
T98
T99
T100
Description
LEDEN Period
LDS2_0 Setup Time
LDS2_0 Hold Time
LED7_0 Setup Time
LED7_0 Hold Time
Note :
Where LED7_0 definition relative to LDS2_0 configuration, please reference pin description of LDS2_0
P/N:PM0427
REV. 1.4, JUL. 8, 1998
33
MX98745
10.0 PACKAGE INFORMATION
160-PIN PLASTIC QUAD FLAT PACK
P/N:PM0427
REV. 1.4, JUL. 8, 1998
34
MX98745
HISTORY OF CHANGE MADE
Rev. No.
1.1
1.2
1.3
1.4
Description
P 1, 9, 10, 11:Change scale for utilization and collision rate LED display.
P28:Change configuration register (register #31) description.
P30:Change 7.0 ABSOLUTE MAXIMUM RATINGS:Power Dissipation,
from 1500mw to 750mw.
P30:Change 8.0 DC Characteristics:ICC(MAX.), form 300mA to 150mA.
P2:Change expansion port signal name from EPCLK to ANYACT.
P/N:PM0427
Date
JAN. 31, 1997
MAR. 12, 1997
JUL. 03, 1997
JUL. 10, 1998
REV. 1.4, JUL. 8, 1998
35
MX98745
MACRONIX INTERNATIONAL CO., LTD.
HEADQUARTERS:
TEL:+886-3-578-8888
FAX:+886-3-578-8887
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FAX:+32-2-456-8021
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FAX:+81-44-246-9105
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FAX:+65-748-4090
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FAX:+1-408-453-8488
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TEL:+1-847-963-1900
FAX:+1-847-963-1909
http : //www.macronix.com
MACRONIX INTERNATIONAL CO., LTD. reserves the rignt to change product and specifications without notice.
36