Zarlink MVTX1100 9-port home pna packet concentrator Datasheet

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MVTX1100
9-Port Home PNA Packet Concentrator
Data Sheet
Features
November 2003
•
8 1/10 Mbps Serial ports direct interface with
Home PNA PHY or 8 10/100 Mbps RMII ports
•
Ideal for MDU (Multiple Dwelling Unit) application
with Home PNA PHY
•
1 10/100 Mbps auto-negotiating MII/serial port
(port 8) that can be used as uplink port
•
Up to 8 port-based VLANs can be configured
from EEPROM
•
Ability to support WinSock 2.0 and Windows 98 &
Windows 2000 smart applications
•
Internal 1 k MAC address table
•
Transmit delay control capabilities
•
-
Auto address learning
-
Auto address aging
Ordering Information
MVTX1100AL 208 Pin PQFP
-40°C to +85°C
-
Provides maximum delay guarantee
(<1 ms)(Last bit in to first bit out)
-
Supports mixed voice-data networks
Leading edge QoS capabilities provided based on
802.1 p and IP TOS/DS field
•
Support Concentrator mode
-
2 queues per output port
•
-
Packet scheduling based on Weighted RoundRobin (WRR)
Ports 0 & 1 can be trunked to provide a
2x1/10 Mbps link to another switch or server
•
-
Weighted Random Early Detection/Drop
(WRED) to drop packets during traffic
congestion
Utilizes a single low-cost external pipelined,
SyncBurst SRAM (SBRAM) for buffer memory
•
External I2C EEPROM for power-up configuration
2 levels of packet drop provided
•
Support external parallel port for configuration
updates
•
Optimized pin-out for easy board layout
•
Packaged in a 208 PQFP
•
Supports both Full/Half duplex ports
•
Full wire-speed layer 2 switching on all ports
S
S
R
A
M
-
MVTX1100
9-Port Home PNA
Packet Concentrator
56 k bytes or 512 k bytes (1 chip)
10/100
MII
CPU
1/10MB*
Serial
Interface
Home
PNA
PHY
Home
PNA
PHY
8 Port Home PNA
+ 1-Port MII Switch
* also supports 10/100MB RMII Interface
Figure 1 - System Block Diagram
1
Zarlink Semiconductor Inc.
Zarlink, ZL and the Zarlink Semiconductor logo are trademarks of Zarlink Semiconductor Inc.
Copyright 2003, Zarlink Semiconductor Inc. All Rights Reserved.
MVTX1100
Data Sheet
Description
The MVTX1100 is a fully integrated 9-port Ethernet packet concentrator designed to support Home Networking. It is
ideal for Multiple Dwelling Units (MDU) application. The MVTX1100 provides features normally not associated with
plug-and-play technology without requiring an external processor to facilitate their utilization.
The MVTX1100 begins operating immediately at power-up, learning addresses automatically and forwarding
packets at full wire speed to any of its 8 output ports or the uplink expansion port. At power-up, MVTX1100
configures itself from the EEPROM, and can then provide port trunking, port-based VLANs, and Quality of Service
(QoS) capabilities, usually associated only with managed switches.
The proprietary built-in intelligence of the MVTX1100 allows it to recognize and offer packet prioritization QoS.
Packets are prioritized based on their layer 2 VLAN priority tag or layer 3 Type-Of Service/ Differentiated Services
(TOS/DS) field. This priority can be defined as transmit and/or drop priority.
The MVTX1100 can be used to create an 8-port unmanaged switch with one WAN router port by adding a CPU
(ARM or MPC 850) connected to the additional MII port (port 8). The only external components needed for a low
cost MDU system are the Home PNA physical layer transceivers and a single SBRAM per MVTX1100.
Operating at 50 MHz internally, and with a 50 MHz interface to the external SBRAM, the MVTX1100 sustains full
wire-speed switching on all 9 ports. When the system supports 8 ports of 1 M Home PNA PHY with the 10M Serial
uplink, the system clock can be operated to 20 MHz and still achieve full wire-speed switching on all nine ports.
The chip is packaged in a small 208 pin Plastic Quad Flat-Pak (PQFP) package.
2
Zarlink Semiconductor Inc.
MVTX1100
Data Sheet
LA_[6]
VSS
L_A[5]
L_A[4]
L_A[3]
L_A[18]
VDD
L_D[31]
L_D[30]
L_D[29]
VSS (CORE)
L_D[28]
L_D[27]
L_D[26]
VDD
L_D[25]
L_D[24]
L_D[23]
L_D[22]
VSS
L_D[21]
L_D[20]
L_D[19]
L_D[18]
VDD (CORE)
L_D[17]
L_D[16]
L_D[15]
VSS
L_D[14]
L_D[13]
L_D[12]
L_D[11]
VDD
L_D[10]
L_D[9]
L_D[8]
VSS (CORE)
L_D[7]
L_D[6]
L_D[5]
L_D[4]
VDD
L_D[3]
L_D[2]
L_D[1]
VSS
L_D[0]
L_A[15]
VDD (CORE)
L_A[16]
L_ADSC#
MVTX1100 Physical Pinout
208 206 204 202 200 198 196 194 192 190 188 186 184 182 180 178 176 174 172 170 168 166 164 162 160 158
2
4
+
154
Buffer Mem Interface
152
Pin 1 I.D.
6
156
150
8
148
10
146
12
144
14
Config Interfaces
142
18
20
22
24
26
28
30
RMII Port Interfaces
16
140
138
136
134
132
130
128
126
32
124
34
122
36
120
MII Port Interfaces
38
40
42
44
46
48
50
RMII Port Interfaces
118
116
114
112
110
108
106
52
54
56
58
60
62
64
66
68
70
72
74
76
78
80
82
84
86
88
90
92
94
96
98 100 102 104
M4_CLS
M4_LINK
M4_DUPLEX
M5_CLS
M5_LINK
M5_DUPLEX
VDD
M4_TXEN
M4_TXD
M4_TXCLK
M4_CRS_DV
M4_RXD
M4_RXCLK
VSS
M5_TXEN
M5_TXD
M5_TXCLK
M5_CRS_DV
M5_RXD
M5_RXCLK
VDD (CORE)
M6_TXEN
M6_TXD
M6_TXCLK
M6_CRS_DV
M6_RXD
M6_RXCLK
VSS (CORE)
M7_TXEN
M7_TXD
M7_TXCLK
M7_CRS_DV
M7_RXD
M7_RXCLK
VDD
M6_CLS
M6_LINK
M6_DUPLEX
M7_CLS
M7_LINK
M7_DUPLEX
VSS
M_CLK
VDD (CORE)
M8_RXDV
M8_COL
VSS
M8_RXCLK
VDD
M8_RXD[0]
M8_RXD[1]
M8_RXD[2]
L_A[7]
L_A[8]
VDD_CORE
L_A[9]
L_A[10]
L_A[11]
VSS
L_A[12]
L_A[13]
L_A[14]
VDD
M0_CLS
M0_LINK
M0_DUPLEX
M1_CLS
M1_LINK
M1_DUPLEX
VSS (CORE)
M0_TXEN
M0_TXD
M0_TXCLK
M0_CRS_DV
M0_RXD
M0_RXCLK
VDD
M1_TXEN
M1_TXD
M1_TXCLK
M1_CRS_DV
M1_RXD
M1_RXCLK
VSS
M2_TXEN
M2_TXD
M2_TXCLK
M2_CRS_DV
M2_RXD
M2_RXCLK
VDD (CORE)
M3_TXEN
M3_TXD
M3_TXCLK
M3_CRS_DV
M3_RXD
M3_RXCLK
VSS (CORE)
M2_CLS
M2_LINK
M2_DUPLEX
M3_CLS
M3_LINK
M3_DUPLEX
3
Zarlink Semiconductor Inc.
L_OE#
L_WE#
VSS
L_CLK
VDD
L_A[17]
L_A[2]
VSS
SCLK
VDD
MIR_CTL[3]
MIR_CTL[2]
MIR_CTL[1]
MIR_CTL[0]
RSTIN#
RSTOUT#
VSS (CORE)
T_MODE
TSTOUT[7]
TSTOUT[6]
TSTOUT[5]
TSTOUT[4]
TSTOUT[3]
TSTOUT[2]
TSTOUT[1]
TSTOUT[0]
VDD (CORE)
ACK
DATA0
STROBE
TRUNK_EN
TEST#
SDA
SCL
M_MDIO
VSS
M_MDC
VDD
M8_REFCLK
VSS
M8_SPEED
M8_DUPLEX
M8_LINK
M8_TXD[3]
M8_TXD[2]
M8_TXD[1]
M8_TXD[0]
M8_TXEN
VDD
M8_TXCLK
VSS (CORE)
M8_RXD[3]
MVTX1100
Pin Reference Table
Pin #
Pin Name
1
L_A[7]
2
L_A[8]
3
VDD (CORE)
4
L_A[9]
5
L_A[10]
6
L_A[11]
7
VSS
8
L_A[12]
9
L_A[13]
10
L_A[14]
11
VDD
12
M0_CLS
13
M0_LINK
14
M0_DUPLEX
15
M1_CLS
16
M1_LINK
17
M1_DUPLEX
18
VSS (CORE)
19
M0_TXEN
20
M0_TXD/(M0_TXD[0])1
21
M0_TXCLK/(M0_TXD[1])
22
M0_CRS_DV
23
M0_RXD/(M0_RXD[0])
24
M0_RXCLK/(M0_RXD[1])
25
VDD
26
M1_TXEN
27
M1_TXD/(M1_TXD[0])
28
M1_TXCLK/(M1_TXD[1])
29
M1_CRS_DV
30
M1_RXD/(M1_RXD[0])
31
M1_RXCLK/(M1_RXD[1])
32
VSS
33
M2_TXEN
34
M2_TXD/(M2_TXD[0])
Data Sheet
35
M2_TXCLK/M2_TXD[1])
70
M5_CRS_DV
36
M2_CRS_DV
71
M5_RXD/(M5_RXD[0])
37
M2_RXD/(M2_RXD[0])
72
38
M2_RXCLK/
(M2_RXD[1])
M5_RXCLK/
(M5_RXD[1])
73
VDD (CORE)
39
VDD (CORE)
74
M6_TXEN
40
M3_TXEN
75
M6_TXD/(M6_TXD[0])
41
M3_TXD/(M3_TXD[0])
76
42
M3_TXCLK/(M3_TXD[1])
M6_TXCLK/
(M6_TXD[1])
43
M3_CRS_DV
77
M6_CRS_DV
44
M3_RXD/(M3_RXD[0])
78
M6_RXD/(M6_RXD[0])
45
M3_RXCLK/(M3_RXD[1])
79
M6_RXCLK/
(M6_RXD1])
46
VSS (CORE)
80
VSS (CORE)
47
M2_CLS
81
M7_TXEN
48
M2_LINK
82
M7_TXD/(M7_TXD[0])
49
M2_DUPLEX
83
M7_TXCLK/(M7_TXD[1])
50
M3_CLS
84
M7_CRS_DV
51
M3_LINK
85
M7_RXD/(M7_RXD[0])
52
M3_DUPLEX
86
M7_RXCLK/(M7_RXD[1])
53
M4_CLS
87
VDD
54
M4_LINK
88
M6_CLS
55
M4_DUPLEX
89
M6_LINK
56
M5_CLS
90
M6_DUPLEX
57
M5_LINK
91
M7_CLS
58
M5_DUPLEX
92
M7_LINK
59
VDD
93
M7_DUPLEX
60
M4_TXEN
94
VSS
61
M4_TXD/(M4_TXD[0])
95
M_CLK
62
M4_TXCLK/(M4_TXD[1])
96
VDD (CORE)
63
M4_CRS_DV
97
M8_RXDV/S8_CRS_DV
64
M4_RXD/(M4_RXD[0])
98
M8_COL/S8_COL
65
M4_RXCLK/(M4_RXD[1])
99
VSS
66
VSS
100
M8_RXCLK/S8_RXCLK
67
M5_TXEN
101
VDD
68
M5_TXD/(M5_TXD[0])
102
M8_RXD[0]/S8_RXD
69
M5_TXCLK/M5_TXD[1])
103
M8_RXD[1]
4
Zarlink Semiconductor Inc.
MVTX1100
Data Sheet
104
M8_RXD[2]
139
T_MODE
175
VDD
105
M8_RXD[3]
140
VSS (CORE)
176
L_D[11]
106
VSS (CORE)
141
RSTOUT#
177
L_D[12]
107
M8_TXCLK/S8_TXCLK
142
RSTIN#
178
L_D[13]
108
VDD
143
(MIRROR_CONTROL[0])
179
L_D[14]
109
M8_TXEN[0]/S8_TXEN
144
(MIRROR_CONTROL[1])
180
VSS
110
M8_TXD[0]/S8_TXD
145
(MIRROR_CONTROL[2])
181
L_D[15]
111
M8_TXD[1]
146
(MIRROR_CONTROL[3])
182
L_D[16]
112
M8_TXD[2]
147
VDD
183
L_D[17]
113
M8_TXD[3]
148
SCLK
184
VDD (CORE)
114
M8_LINK/S8_LINK
149
VSS
185
L_D[18]
115
M8_DUPLEX/S8_DUPLE
X
150
L_A[2]
186
L_D[19]
151
L_A[17]
187
L_D[20]
116
M8_SPEED
152
VDD
188
L_D[21]
117
VSS
153
L_CLK
189
VSS
118
M8_REFCLK
154
VSS
190
L_D[22]
119
VDD
155
L_WE#
191
L_D[23]
120
M_MDC
156
L_OE#
192
L_D[24]
121
VSS
157
L_ADSC#
193
L_D[25]
122
M_MDIO
158
L_A[16]
194
VDD
123
SCL
159
VDD (CORE)
195
L_D[26]
124
SDA
160
L_A[15]
196
L_D[27]
125
TEST#
161
L_D[0]
197
L_D[28]
126
TRUNK_ENABLE
162
VSS
198
VSS (CORE)
127
STROBE
163
L_D[1]
199
L_D[29]
128
DATA0
164
L_D[2]
200
L_D[30]
129
ACK
165
L_D[3]
201
L_D[31]
130
VDD (CORE)
166
VDD
202
VDD
131
TSTOUT[0]
167
L_D[4]
203
L_A[18]
132
TSTOUT[1]
168
L_D[5]
204
L_A[3]
133
TSTOUT[2]
169
L_D[6]
205
L_A[4]
134
TSTOUT[3]
170
L_D[7]
206
L_A[5]
135
TSTOUT[4]
171
VSS (CORE)
207
VSS
136
TSTOUT[5]
172
L_D[8]
208
L_A[6]
137
TSTOUT[6]
173
L_D[9]
Note 1:
138
TSTOUT[7]
174
L_D[10]
5
Zarlink Semiconductor Inc.
Pin names inside ( ) indicate
RMII pins for ports 0-7.
MVTX1100
S
S
R
A
M
MVTX1100
Switch Chip
1-Port MII 10/100
8-Port 10 MB Serial
10/100
MII
Data Sheet
PAL
10 MB
Serial
Interface
Home
PNA
PHY
10/100
RMII
MVTX2604
Routing Switch 1 G GMII
24 10/100 Ports
+
2-1 G Uplinks
.
.
.
Home
PNA
PHY
Line Card
192+2 Port Switch
MDU System
10 Mbps Serial
Interface
S
S
R
A
M
MVTX1100
8-Port 1 MB Serial
MVTX1100
1 MB
Serial
Interface
Home
PNA
PHY
10/100 MII
Home
PNA
PHY
Line Card
64+1 Port Switch
MDU System
Figure 2 - System Block Diagram (High Port Density MDU System)
6
Zarlink Semiconductor Inc.
MVTX1100
1k
Figure 3 - MVTX1100 Block Diagram
7
Zarlink Semiconductor Inc.
Data Sheet
MVTX1100
1.0
Data Sheet
Functional Operation
The MVTX1100 was designed to provide a cost-effective layer 2 switching solution, using technology from the
Zarlink family to offer a highly integrated product for the unmanaged, DiffServ ready, Ethernet switching market.
Nine 1/10 Media Access Controllers (MAC) provide the protocol interface into the MVTX1100. These MACs perform
the required packet checks to ensure that each packet provided to the Frame Engine meets all the IEEE 802.1
standards. Data packets longer than 1518 (1522 with VLAN tag) bytes and shorter than 64 bytes are dropped and
MVTX1100 has been designed to support minimum inter-frame gaps between incoming packets.
The PHY addresses for the 8 RMII MACs are from 08h to 0Fh. These eight ports are denoted as ports 0 to 7. The
PHY address for the uplink MAC is 10h. This port is denoted as port 8.
The Frame Engine (FE) is the primary packet buffering and forwarding engine within the MVTX1100. As such, the
FE controls the storage of packets in and out of the external frame buffer memory, keeps track of frame buffer
availability and schedules output packet transmissions. While packet data is being buffered, the FE extracts the
necessary information from each packet header and sends it to the Search Engine for processing. Search results
returned to the FE ensue the scheduling of packet transmission and prioritization. When a packet is chosen for
transmission, the FE reads the packet from external buffer memory and places it in the output FIFO of the output
port.
2.0
Address Learning and Aging
The MVTX1100 is able to begin address learning and packet forwarding shortly after powerup has been completed.
The Search Engine examines the contents of its internal Switch Database Memory for each valid packet received
on an input port.
Unknown source and destination MAC addresses are detected when the Search Engine does not find a match
within its database. These unknown source MAC addresses are learned by creating a new entry in the switch
database memory, and storing the necessary resulting information in that location. Subsequent searches to a
learned destination MAC address will return the new contents of that MAC Control Table (MCT) entry.
After each source address search the MCT entry aging flag is updated. MCT entries that have not been accessed
during a user configurable time period (2 to 67,108 seconds) will be removed. This aging time period can be
configured using the 16-bit value stored in the registers MAC Address Aging Time Low and High (MATL[7:0],
MATH[7:0]). The aging period is defined by the following equation:
{MATH[7:0]&MATL[7:0]} x 1024ms = Tage
The aging of all MCT entries is checked once during each time period. If the MCT entry has not been utilized before
the end of the next time period, it will be deleted.
Note that when the system clock operates at 20 MHz, the aging period will be increased, compared with 50 MHz of
system clock. One should adjust the MATH and MATHL content variable accordingly.
3.0
Quality of Service
The MVTX1100 utilizes Zarlink’s architecture that provides a new level of (QoS) capability to unmanaged switch
applications. Similar in operation to the QoS capabilities of other Zarlink chipset members, MVTX1100 provides two
transmit queues per output port.
The Frame Engine manages the output transmission queues for all the MVTX1100 ports. Once the destination
address search is complete, and the switch decision is passed back to the FE, the packet is inserted into the
appropriate output queue. The packet entry into the high or low priority queue is controlled by either the VLAN tag
information or the Type of Service/Differentiated Service (TOS/DS) field in the IP header. Either of these priority
fields can be used to select the transmission priority, and the mapping of the priority field values into either the high
or low priority queue can be configured using the MVTX1100 configuration registers.
8
Zarlink Semiconductor Inc.
MVTX1100
Data Sheet
If the system uses the TOS/DS field to prioritize packets, there are two choices regarding which bits of the TOS/DS
field are used. Bits [0:2] of the TOS byte (known as the IP precedence field) or bits [3:5] of the TOS byte (known as
the DRT field) can be used to map the transmission queue priority. Either bits, [0:2] or [3:5], can also be used as a
packet drop precedence, by using bits 6 and 7 of the FCB Buffer Low Threshold register (FCBST).
MVTX1100 utilizes Weighted Round Robin (WRR) and Weighted Random Early Detection/Drop (WRED) to
schedule packets for transmission. To enable MVTX1100’s QoS capabilities requires the use of an external
EEPROM to change the default register configurations and turn on QoS.
Weighted Round Robin is an efficient method to ensure that each of the transmission queues gets at least a
minimum service level. With two output transmission queues, MVTX1100 will transmit “X” packets from the high
priority queue before transmitting “Y” packets from the low priority queue. MVTX1100 allows the designer to set the
high priority weight to a value between 0 and 16. The low priority weight is fixed at the value 1. If the high priority
weight is set to the value 4, then it will transmit 4 high priority packets before transmitting each low priority packet.
MVTX1100 also uses a proprietary mechanism to ensure the timely delivery of high priority packets. When the
latency of high priority packets reaches a threshold, it will override the WRR weights and transmit only high priority
packets until the high priority packet delays are below the threshold. This threshold limit is set at less than 1 ms
(last bit in and first bit out).
The QoS capabilities of the MVTX1100 are enabled by loading the appropriate values into the configuration
registers. QoS for packet transmission is enabled by performing the following four steps:
1. Select the TOS/DS or VLAN Priority Tag field as the control for IP packet transmission. The selection is made
using bit 7 of the Flooding Control (FCR[7]) register.
-
FCR[7]=0, use VLAN Priority Tag field to map the transmission priority if this Tag field exists.
-
FCR[7]=1, use TOS/DS field for IP packet transmission priority mapping.
2. Select which TOS/DS field to use as the control for packet transmission priority if the TOS/DS field was selected
in step 1. The selection is made using bit 6 of the FCB Buffer Low Threshold (FCBST[6]) register.
-
FCBST[6]=0, use DTR subfield to map the transmission priority.
-
FCBST[6]=1, use IP precedence subfield1 to map the transmission priority.
3. Set the transmission queue weight for the high priority queue in the Transmission Scheduling Control
(AXSC[3:0]) register.
4. Set the priority mappings from the TOS/DS or VLAN Priority Tag field to the high or low priority output queue.
The selection is made using the VLAN Priority Map (AVPM) and TOS Priority Map (TOSPML) registers.
Note that, for half duplex operation, the priority queues2 must be enabled using bit 7 in the Transmission
Scheduling Control (AXSC[7]) register to utilize the QoS function.
When QoS is enabled, MVTX1100 will utilize WRR to schedule packet transmission, and will use Weighted
Random Early Detection/Drop (WRED) to drop random packets in order to handle buffer memory congestion. In
this method, only certain packet flows are slowed down while the remaining see no impact from the network traffic
congestion.
Weighted Random Early Detection/Drop (WRED) is a method of handling traffic congestion in the absence of flow
control mechanisms. When flow control is enabled, all devices that are connected to a switch node that is
exercising flow control are effectively unable to transmit, including nodes that are not directly responsible for the
congestion problem. This inability to transmit during flow control periods would play havoc with voice packets, or
other high priority packet flows, and therefore flow control is not recommended for networks that mix voice and data
traffic.
1. IP precedence and DTR subfields are referred to as TOS/DS[0:2] and TOS/DS[3:5] in the IP TOS/DS byte.
2. In Half Duplex mode, the QoS functions are disabled by default.
9
Zarlink Semiconductor Inc.
MVTX1100
Data Sheet
WRED allows traffic to continue flowing into ports on a switch, and randomly drops packets with different
probabilities based upon each packet’s priority markings. As the switch congestion increases, the probability of
dropping an input packet increases, and as congestion decreases, the probability of dropping an input packet
decreases. In this manner, only traffic flows that have had packets dropped will be affected by the congestion. Other
traffic flows will see no effect.
The following table summarizes the WRED operation of the MVTX1100. It lists the buffer thresholds at which each
drop probability takes effect.
WRED Threshold
Condition for High
Priority Queue
Level 0
Level 1
Drop Percentage
Condition for Low
Priority Queue
Drop Percentage for
High-Drop Packet
Drop Percentage for
Low-Drop Packet
50%
0%
72 buffers occupied
75%
25%
84 buffers occupied
100%
50%
Total buffer space available in device is
≤LPBT
24 buffers occupied
Level 2
Table 1 - WRED Operation of the MVTX1100
The WRED packet drop capabilities of MVTX1100 are enabled by performing the following three steps:
1. Select the TOS/DS or VLAN Tag field as the control for packet dropping. The selection is made using bit 7 of the
Flooding Control (FCR[7]) register.
-
FCR[7]=0, use VLAN Priority Tag field to map the drop priority if this Tag field exists
-
FCR[7]=1, use ToS/DS field for IP packet transmission priority mappin.
2. Select which TOS/DS Tag field to use for packet dropping provided that the TOS/DS field was selected in step 1.
The selection is made using bit 7 of the FCB Buffer Low Threshold (FCBST[7]) register.
-
FCBST[7]=0, use DTR subfield to map the drop priority
-
FCBST[7]=1, use IP precedence subfield to map the drop priority
3. Set the drop mappings from the TOS/DS or VLAN Tag field to the high or low drop priority output flag. The selection is made using the VLAN Drop Map (AVDM) and TOS Discard Map (TOSDML) registers.
Note that to utilize the QoS function of the MVTX1100, flow control has to be disabled.
4.0
Buffer Management
MVTX1100 stores each input packet into the external frame buffer memory while determining the destination the
packet is to be forwarded to. The total number of packets that can be stored in the frame buffer memory depends
upon the size of the external SBRAM that is utilized. For a 256 k byte SBRAM MVTX1100 can buffer 170 packets.
For a 512 K byte SBRAM MVTX1100 can buffer 340 packets.
In order to provide good QoS characteristics, MVTX1100 must allocate the available buffer space to low and high
priority unicast and multicast traffic. This can be accomplished using the external EEPROM to load the appropriate
values into MVTX1100 configuration registers. To allow the designer to set the minimum number of buffers provided
for low drop priority unicast traffic, use the Low Drop Priority Buffer Threshold (LPBT[7:0]) register. To set the
maximum number of buffers allocated for all multicast packets, use the Multicast Buffer Control (MBCR[7:0])
register. During operation MVTX1100 will continuously monitor the amount of frame buffer memory that is available,
and when the unused buffer space falls below a designer configurable threshold, MVTX1100 will begin to drop
incoming packets (WRED). This threshold is set using the FCB Buffer Low Threshold (FCBST[5:0]) register.
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Zarlink Semiconductor Inc.
MVTX1100
5.0
Data Sheet
Virtual LANs
MVTX1100 provides the designer the ability to define a single port-based Virtual LAN (VLAN) for each of the nine
ports. This VLAN is individually defined for each port using the Port Control Registers (ECR1Px[6:4]). Bits [6:4]
allow the designer to define a VLAN ID (value between 0-7) for each port.
When packets arrive at an input of MVTX1100, the search engine will determine the VLAN ID for that port, and then
determine which of the other ports also are members of that VLAN by matching their assigned VLAN Id values. The
packet will then be transmitted to each port with the same VLAN ID as the source port.
6.0
Concentration Mode
MVTX1100 supports a Concentration Mode, where each of the 0-7 port is only allowed to directly communicate with
the uplink port 8. This mode ensures that data from any of ports 0-7 cannot be directly seen by any other port. This
feature is used in MDU applications to provide data privacy to subscribers.
To use this mode, a CONC (concentration) bit in each ECR1 register of ports 0-8 must be enabled, i.e., ECR1 [7]=1,
and ports 0-7 must each be set on a separate VLAN. Note that, in concentration mode, the VLAN of port 8 will be
ignored.
A more flexible concentration mode can be set up. For this mode, ports 0–7 are partitioned into several groups,
sharing the same VLAN ID. This will allow traffic within the same group to freely communicate with each other, while
continuing to communicate outside the group in concentration mode.
7.0
Port Trunking
Port trunking allows the designer to configure the MVTX1100, such that ports 0 and 1 are defined as a logical port.
This provides a 20Mb/s link to a switch or server using two 10Mb/s ports in parallel.
Ports 0 and 1 can be trunked by pulling the TRUNK_EN pin to the high state. In this mode, the source MAC address
of all packets received from the trunk are checked against the MCT database to ensure that they have a port ID of
0 or 1. Packets that have a port ID other than 0 and 1 will effect the MVTX1100 to learn the new MAC address for
this port change.
On transmission, the selected trunk port is determined by hashing the source and destination MAC addresses. This
provides a one-to-one mapping between the trunk port and the MAC addresses. Subsequent packets with the
same MAC addresses will always utilize the same trunk port.
MVTX1100 also provides a safe fail-over mode for port trunking. If one of the two ports goes down, via the ports link
signal, MVTX1100 will switch all traffic destined to the failed port over to the remaining port in the trunk. Thus
maintaining the trunk link, albeit at a lower effective bandwidth.
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Zarlink Semiconductor Inc.
MVTX1100
8.0
Data Sheet
Port Mirroring
The port mirroring function is only supported in RMII mode. Using the 4 port mirroring control pins provides the
ability to enable or disable port mirroring, select which of the remaining 7 ports is to be mirrored and whether the
received or transmitted data is being mirrored. The control for this function is shown in the following table.
Mirrored Port
Mirror_Control [3]
Mirror_Control [2]
Mirror_Control [1]
Mirror_Control [0]
Port 0 RX
1
0
0
0
Port 0 TX
0
0
0
0
Port 1 RX
1
0
0
1
Port 1 TX
0
0
0
1
Port 2 RX
1
0
1
0
Port 2 TX
0
0
1
0
Port 3 RX
1
0
1
1
Port 3 TX
0
0
1
1
Port 4 RX
1
1
0
0
Port 4 TX
0
1
0
0
Port 5 RX
1
1
0
1
Port 5 TX
0
1
0
1
Port 6 RX
1
1
1
0
Port 6 TX
0
1
1
0
Disabled
X
1
1
Table 2 - Port Mirroring Configuration
1
When enabled, port mirroring will allow the user to monitor traffic going through the switch on output Port 7. If the
port mirroring control pins, Mirror_Control[3:0], are left floating, MVTX1100 will operate with the port mirroring
function disabled.
When port mirroring is enabled, the user must configure Port 7 to operate in the same mode as the port it is
mirroring (autoneg, duplex, speed, flow control).
9.0
Power Saving Mode in MAC
The power saving mode is activated only in RMII mode. MVTX1100 was designed to be power efficient. When the
internal RMII MAC sections detect that the external port is not receiving or transmitting packets, it will shut down
and conserve power. When new packet data is loaded into the output transmit FIFO of a MAC in power saving
mode, the MAC will return to life and begin operating immediately.
When the MAC is in power saving mode and new packet data is received on the RMII interface, the MAC will return
to life and receive data normally into the receive FIFO. This wake up occurs when the MAC sees the CRS_DV
signal asserted.
Using this method, the switch will turn off all MAC sections during periods when there is no network activity (at night
for example), and save power. For large networks this power savings can be significant. To achieve the maximum
power efficiency, the designer should use a physical layer transceiver that utilizes “Wake-On-LAN” technology.
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Zarlink Semiconductor Inc.
MVTX1100
10.0
Data Sheet
EEPROM I2C Interface
A simple 2 wire serial interface is provided to allow the configuration of the MVTX1100 via an external EEPROM.
MVTX1100 utilizes a 1 K bit EEPROM with an I2C interface.
11.0
Management Interface
MVTX1100 uses a standard parallel port interface to provide external CPU access to the internal registers. This
parallel interface consists of 3 pins: DATA0, STROBE and ACK. The DATA0 pin provides the address and data
content input to MVTX1100, while the ACK pin provides the corresponding output to the external CPU. The
STROBE pin is provided as the clock for both serial data streams. Any of its internal registers can be modified
through this parallel port interface.
Figure 4 - Write Command
Figure 5 - Read Command
Each management interface transfer consists of four parts:
1. A START pulse – occurs when DATA is sampled high when STROBE is rising followed by DATA being sampled
low when STROBE falls.
2. Register Address strobed into DATA0 pin by the high level of the STROBE pin.
3. Either a Read or Write Command (see waveforms above).
4. Data to be written provided on DATA0, or data to be read back provided on ACK.
Any command can be aborted in the middle by sending an ABORT pulse to MVTX1100. An ABORT pulse occurs
when DATA is sampled low and STROBE is rising, then DATA is sampled high when STROBE falls.
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Zarlink Semiconductor Inc.
MVTX1100
12.0
Data Sheet
Configuration Register Definitions
MVTX1100 registers can be accessed via the parallel interface and/or the I 2C interface. Some registers are only
accessible through the parallel interface. The access method for each register is listed in the individual register
definitions. Each register is 8-bit wide.
12.1
GCR - Global Control Register
•
Access: parallel interface, Write Only
•
Address: h30
12.2
Bit 0
Save configuration into EEPROM
Write '1' followed by a '0'
(Default = 0)
Bit 1
Save configuration into EEPROM and reset
system
Write '1' (self-clearing due to reset)
(Default = 0)
Bit 2
Start Built-In Self-Test (BIST)
Write '1' followed by a '0'
(Default = 0)
Bit 3
Reset system
Write '1' (self-clearing due to reset)
(Default = 0)
Bit [7:4]
Reserved
DCR - Device Status and Signature Register
•
Access: parallel interface, Read Only
•
Address: h31
Bit 0
Busy writing configuration from I2C
1: Activity
0: No Activity
Bit 1
Busy reading configuration from I2C
1: Activity
0: No Activity
Bit 2
Built-In Self-Test (BIST) in progress
1: BIST In-Progress
0: Normal Mode
Bit 3
RAM error during BIST
1: RAM Error
0: No Error
Bit [5:4]
Reserved
Bit [7:6]
Revision number
00: Initial Silicon
01: Second Silicon
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Zarlink Semiconductor Inc.
MVTX1100
12.3
Data Sheet
DA – DA Register
•
Access: parallel interface, Read Only
•
Address: h36
Always returns 8-bit value hDA. Indicates the (Default DA) parallel port connection is good.
12.4
MBCR – Multicast Buffer Control Register (Address H00)
•
Access: parallel interface and I2C, Read/Write
•
Address: h00
Bit [7:0]
12.5
MAX_CNT_LMT
Maximum number of
multicast frames allowed
(Default = 80)
FCBST – FCB Buffer Low Threshold
•
Access: parallel interface and I2C, Read/Write
•
Address: h01
Bits [5:0]
BUF_LOW_TH
Buffer Low Threshold –
number of FCB left before
triggering WRED
(Default = 3F)
Bit 6
Use IP precedence field
(TOS[0:2]) for Priority
(Default = 0)
Bit 7
Use IP precedence subfield
(TOS[0:2]) for Drop
(Default = 0)
Note that, for Bits 6 and 7, Default = 0 means to
use DTR filed (TOS[3:5]).
12.6
LPBT – Low Drop Priority Buffer Threshold
•
Access: parallel interface and I2C, Read/Write
•
Address: h02
Bit [7:0]
12.7
LOW_PRI_CNT
Number of frame buffers
reserved for low-dropping
traffic
(Default 3F)
FCR – Flooding Control Register
•
Access: parallel interface and I2C, Read/Write
•
Address: h03
Bits [3:0]
U2MR
Unicast to Multicast Rate
(Default = 8)
Bits [6:4]
TimeBase
000 = 100 µs 001 = 200 µs
010 = 400 µs 011 = 800 µs
100 = 1.6 ms 101 = 3.2 ms
110 = 6.4 ms 111 = 100 µs
(Default = 000)
Bit 7
USE_TOS
Pick TOS over VLAN
priority for IP Packet.
(Default = 0)
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MVTX1100
12.8
AVTCL – VLAN Type Code Register Loq
•
Access: parallel interface and I2C, Read/Write
•
Address: h04
Bit [7:0]
12.9
VLANType_LOW
Lower 8 bits of VLAN type
code.
(Default 00)
AVTCH – VLAN Type Code Register High
•
Access: parallel interface and I2C, Read/Write
•
Address: h05
Bit [7:0]
12.10
Data Sheet
VLANType_HIGH
Upper 8 bits of the VLAN
type code
(Default 81)
AVPM – VLAN Priority Map
•
Access: parallel interface and I2C, Read/Write
•
Address: h06
Map VLAN tag into 2 transmit queues (0 = low priority, 1 = high priority)
12.11
Bit 0
Mapped priority of tag value 0
(Default 0)
Bit 1
Mapped priority of tag value 1
(Default 0)
Bit 2
Mapped priority of tag value 2
(Default 0)
Bit 3
Mapped priority of tag value 3
(Default 0)
Bit 4
Mapped priority of tag value 4
(Default 0)
Bit 5
Mapped priority of tag value 5
(Default 0)
Bit 6
Mapped priority of tag value 6
(Default 0)
Bit 7
Mapped priority of tag value 7
(Default 0)
AVDM – VLAN Discard Map
•
Access: parallel interface and I2C, Read/Write
•
Address: h07
Map VLAN tag into frame discard when low priority buffer usage is above threshold
Bit 0
Frame discard for tag value 0
(Default 0)
Bit 1
Frame discard for tag value 1
(Default 0)
Bit 2
Frame discard for tag value 2
(Default 0)
Bit 3
Frame discard for tag value 3
(Default 0)
Bit 4
Frame discard for tag value 4
(Default 0)
Bit 5
Frame discard for tag value 5
(Default 0)
Bit 6
Frame discard for tag value 6
(Default 0)
Bit 7
Frame discard for tag value 7
(Default 0)
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MVTX1100
12.12
Data Sheet
TOSPML – TOS/DS Priority Map Low
•
Access: parallel interface and I2 C, Read/Write
•
Address: h08
Map TOS field in IP packet into 2 transmit queues (0 = low priority, 1 = high priority).
Bit 0
Mapped priority when TOS is 0
(Default 0)
1
Bit 1
Mapped priority when TOS is 1
(Default 0)
Bit 2
Mapped priority when TOS is 2
(Default 0)
Bit 3
Mapped priority when TOS is 3
(Default 0)
Bit 4
Mapped priority when TOS is 4
(Default 0)
Bit 5
Mapped priority when TOS is 5
(Default 0)
Bit 6
Mapped priority when TOS is 6
(Default 0)
Bit 7
Mapped priority when TOS is 7
(Default 0)
1. TOS = 1 means the appropriate 3-bit TOS subfield is “001.
12.13
TOSDML – TOS/DS Discard Map
•
Access: parallel interface and I2C, Read/Write
•
Address: h0A
Map TOS into frame discard when low priority buffer usage is above threshold
12.14
Bit 0
Frame discard when TOS is 0
(Default 0)
Bit 1
Frame discard when TOS is 1
(Default 0)
Bit 2
Frame discard when TOS is 2
(Default 0)
Bit 3
Frame discard when TOS is 3
(Default 0)
Bit 4
Frame discard when TOS is 4
(Default 0)
Bit 5
Frame discard when TOS is 5
(Default 0)
Bit 6
Frame discard when TOS is 6
(Default 0)
Bit 7
Frame discard when TOS is 7
(Default 0)
AXSC – Transmission Scheduling Control Register
•
Access: parallel interface and I2C, Read/Write
•
Address: h0B
Bits [3:0]:
Transmission Queue Service Weight for high
priority queue
Bit [4]
Reserved
Bit [5]
Reserved
Bit [6]:
Global Flow Control
(Default 0, enable)
Bit [7]:
Half Duplex Priority Enable
(Default 0)
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Zarlink Semiconductor Inc.
(Default F)
MVTX1100
12.15
Data Sheet
MII_OP0 – MII Register Option 0
•
Access by parallel interface and I2C, Read/Write
•
Address: h0C
To provide a non-standard address for the Phy Status Register. When low and high Address bytes are 0,
MVTX1100 will use the standard address. Bit [7:0] Low order address byte (Default 00)
12.16
MII_OP1 – MII Register Option 1
•
Access: parallel interface and I2C, Read/Write
•
Address: h0D
Bit [7:0]
12.17
High order address byte
(Default 00)
AGETIME_LOW – Mac Address Aging Timer Low
Access: parallel interface and I2C, Read/Write
Address: h0E
Bit [7:0]
12.18
Low byte of the MAC address aging timer.
(Default 25)
AGETIME_HIGH – Mac Address Aging Timer High
•
Access: parallel interface and I2C, Read/Write
•
Address: h0F
Bit [7:0]
High byte of the MAC address aging timer.
(Default 01)
The aging time is based on the following formula:
{AGETIME_HIGH, AGETIME_LOW} x 1024 ms.
12.19
ECR1P0 – Port 0 Control Register
•
Access: parallel interface and I2C, Read/Write
•
Address: h10
Bits [3:0]
RMII Port Mode Only for RMII mode,
Serial Mode DON’T CARE
Bit [0]
1 – Flow Control Off
0 – Flow Control On
Bit [1]
1 – Half Duplex
0 – Full Duplex
Bit [2]
1 – 10 Mbps
0 – 100 Mbps
Bit [3]
1 – Force configuration based on
Bits [2:0]
0 – Auto and advertise based on Bits
[2:0]
Bits [6:4]
PVID
Port-based VLAN ID
Bit [7]
CONC:
Enable Concentration Mode
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Zarlink Semiconductor Inc.
(Default 0000)
(Default 000)
MVTX1100
12.20
ECR1P1 – Port 1 Control Register
•
Access: parallel interface and I2C, Read/Write
•
Address: h11
Bits [3:0]
12.21
Data Sheet
RMII Port Mode
Only for RMII mode,
Serial Mode DON’T CARE
Bit [0]
1 – Flow Control Off
0 – Flow Control On
Bit [1]
1 – Half Duplex
0 – Full Duplex
Bit [2]
1 – 10 Mbps
0 – 100 Mbps
Bit [3]
1 – Force configuration based on
Bits [2:0]
0 – Auto and advertise based on
Bits [2:0]
(Default 0000)
Bits [6:4]
PVID
Port-based VLAN ID
(Default 000)
Bit [7]
CONC:
Enable Concentration Mode
(Default 0)
ECR1P2 – Port 2 Control Register
•
Access: parallel interface and I2C, Read/Write
•
Address: h12
Bits [3:0]
RMII Port Mode
Only for RMII mode,(Default
0000)
Serial Mode DON’T CARE
Bit [0]
1 – Flow Control Off
0 – Flow Control On
Bit [1]
1 – Half Duplex
0 – Full Duplex
Bit [2]
1 – 10 Mbps
0 – 100 Mbps
Bit [3]
1 – Force configuration based on
Bits [2:0]
0 – Auto and advertise based on
Bits [2:0]
(Default 0000)
Bits [6:4]
PVID
Port-based VLAN ID
(Default 000)
Bit [7]
CONC:
Enable Concentration Mode
(Default 0)
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MVTX1100
12.22
ECR1P3 – Port 3 Control Register
•
Access: parallel interface and I2C, Read/Write
•
Address: h13
Bits [3:0]
12.23
Data Sheet
RMII Port Mode
Only for RMII mode,
Serial Mode DON’T CARE
Bit [0]
1 – Flow Control Off
0 – Flow Control On
Bit [1]
1 – Half Duplex
0 – Full Duplex
Bit [2]
1 – 10 Mbps
0 – 100 Mbps
Bit [3]
1 – Force configuration based on
Bits [2:0]
0 – Auto and advertise based on
Bits [2:0]
(Default 0000)
Bits [6:4]
PVID
Port-based VLAN ID
(Default 000)
Bit [7]
CONC:
Enable Concentration Mode
(Default 0)
ECR1P4 – Port 4 Control Register
•
Access: parallel interface and I2C, Read/Write
•
Address: h14
Bits [3:0]
RMII Port Mode
Only for RMII mode, (Default
0000)
Serial Mode DON’T CARE
Bit [0]
1 – Flow Control Off
0 – Flow Control On
Bit [1]
1 – Half Duplex
0 – Full Duplex
Bit [2]
1 – 10 Mbps
0 – 100 Mbps
Bit [3]
1 – Force configuration based on
Bit [2:0]
0 – Auto and advertise based on
Bit [2:0]
(Default 0000)
Bits [6:4]
PVID
Port-based VLAN ID
(Default 000)
Bit [7]
Reserved
Enable Concentration Mode
(Default 0)
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MVTX1100
12.24
ECR1P5 – Port 5 Control Register
•
Access: parallel interface and I2C, Read/Write
•
Address: h15
Bits [3:0]
12.25
Data Sheet
RMII Port Mode
Only for RMII mode,
Serial Mode DON’T CARE
Bit [0]
1 – Flow Control Off
0 – Flow Control On
Bit [1]
1 – Half Duplex
0 – Full Duplex
Bit [2]
1 – 10 Mbps
0 – 100 Mbps
Bit [3]
1 – Force configuration based on
Bit [2:0]
0 – Auto and advertise based on
Bits [2:0]
(Default 0000)
Bits [6:4]
PVID
Port-based VLAN ID
(Default 000)
Bit [7]
CONC:
Enable Concentration Mode
(Default 0)
ECR1P6 – Port 6 Control Register
•
Access: parallel interface and I2C, Read/Write
•
Address: h16
Bits [3:0]
RMII Port Mode
Only for RMII mode,
Serial Mode DON’T CARE
Bit [0]
1 – Flow Control Off
0 – Flow Control On
Bit [1]
1 – Half Duplex
0 – Full Duplex
Bit [2]
1 – 10 Mbps
0 – 100 Mbps
Bit [3]
1 – Force configuration based on
Bit [2:0]
0 – Auto and advertise based on
Bit [2:0]
(Default 0000)
Bits [6:4]
PVID
Port-based VLAN ID
(Default 000)
Bit [7]
CONC:
Enable Concentration Mode
(Default 0)
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MVTX1100
12.26
ECR1P7 – Port 7 Control Register
•
Access: parallel interface and I2C, Read/Write
•
Address: h17
Bits [3:0]
12.27
Data Sheet
RMII Port Mode
Only for RMII mode,
Serial Mode DON’T CARE
Bit [0]
1 – Flow Control Off
0 – Flow Control On
Bit [1]
1 – Half Duplex
0 – Full Duplex
Bit [2]
1 – 10 Mbps
0 – 100 Mbps
Bit [3]
1 – Force configuration based on
Bit [2:0]
0 – Auto and advertise based on
Bit [2:0]
(Default 0000)
Bits [6:4]
PVID
Port-based VLAN ID
(Default 000)
Bit [7]
CONC:
Enable Concentration Mode
(Default 0)
ECR1P8 – Port 8 Control Register
•
Access: parallel interface and I2C, Read/Write
•
Address: h18
Bits [3:0]
Port Mode
(Default 0000)
Bit [3]
1 – Force configuration based on
Bit [2:0]
0 – Autonegotiate and advertise
based on Bit[2:0]
Bit [2]
1 – 10 Mbps
0 – 100 Mbps
Bit [1]
1 – Half Duplex
0 – Full Duplex
Bit [0]
1 – Flow Control Off
0 – Flow Control On
Bits [6:4]
PVID
Port-based VLAN ID
(Default 000)
Bit [7]
CONC:
Enable Concentration Mode
(Default 0)
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MVTX1100
12.28
Data Sheet
FC_0 – Flow Control Byte 0
•
Access: parallel interface and I2C, Read/Write
•
Address: h19
The flow control hold time parameter is the length of time a flow control message is effectual (i.e. halts
incoming traffic) after being received. The hold time is measured in units of “slots,” the time it takes to
transmit 64 bytes at wire speed. The default setting is 32 slots, or for a 100 Mbps port, approximately 164 s.
Bits [7:0]
12.29
Flow control hold time byte 0
FC_1 – Flow Control Byte 1
•
Access: parallel interface and I2C, Read/Write
•
Address: h1A
Bits [7:0]
12.30
Flow control hold time byte 1
Access: parallel interface and I2C, Read/Write
•
Address: h1B
Bits [7:0]
Flow control frame CRC byte 0 (Default 96)
FC_3 – Flow Control CRC Byte 1
•
Access: parallel interface and I2C, Read/Write
•
Address: h1C
Bits [7:0]
12.32
Flow control frame CRC byte 1 (Default 8E)
FC_4 – Flow Control CRC Byte 2
•
Access: parallel interface and I2C, Read/Write
•
Address: h1D
Bits [7:0]
12.33
Flow control frame CRC byte 2 (Default 99)
FC_5 – Flow Control CRC Byte 3
•
Access: parallel interface and I2C, Read/Write
•
Address: h1E
Bits [7:0]
12.34
(Default 00)
FC_2 – Flow Control CRC Byte 0
•
12.31
(Default FF)
Flow control frame CRC byte 3 (Default 9A)
CHECKSUM - EEPROM Checksum
•
• Access: parallel interface and I2C, Read/Write
•
• Address: h24
The calculation is [0x100 - ((sum of registers 0x00~0x23) & 0xFF)]. For example, based on the default
register settings, the CHECKSUM value would be 0xEE.
Bits [7:0]
Checksum
(Default 00)
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MVTX1100
13.0
Data Sheet
MVTX1100 Pin Descriptions
Note:
# Active low signal
I
Input signal
S Input signal with Schmitt-Trigger
O Output signal
OD Open-Drain driver
I/O Input & Output signal
SL Slew Rate Controlled
D Pulldown
U Pullup
5 5V Tolerance
Pin No(s).
Symbol
Type
Name & Functions
Frame Buffer Memory Interface
201, 200, 199, 197, 196, 195,
193, 192, 191, 190, 188, 187,
186, 185, 183, 182, 181, 179,
178, 177, 176, 174, 173, 172,
170, 169, 168, 167, 165, 164,
163, 161
L_D[31:0]
I/O, U, SL
Databus to Frame Buffer Memory
203, 151, 158, 160, 10, 9, 8,
6, 5, 4, 2, 1, 208, 206, 205,
204, 150
L_A[18:2]
I/O, U, SL
Address Pins for Buffer Memory
153
L_CLK
O
Frame Buffer Memory Clock
155
L_WE#
O, SL
Frame Buffer Memory Write Enable
156
L_OE#
O
Frame Buffer Memory Output Enable
157
L_ADSC#
O, SL
Address Status Control
120
M_MDC
O
MII Management Data Clock
122
M_MDIO
I/O, U
MII Management Data I/O
MII Management Interface
I2C Interface (Serial EEPROM Interface)
123
SCL
O, U, 5
I2C Data Clock
124
SDA
I/O, U, OD, 5
I2C Data I/O
Parallel Port Management Interface
127
STROBE
I, U, S, 5
Strobe Pin
128
DATA0
I, U, 5
Data Pin
129
ACK
O, U, OD, 5
Acknowledge Pin
M0_RXD
I, U
Port 0 Receive Data
Port 0 Serial Interface
23
24
Zarlink Semiconductor Inc.
MVTX1100
Pin No(s).
Symbol
Data Sheet
Type
Name & Functions
24
M0_RXCLK
I, U
Port 0 Receive Clock
22
M0_CRS_DV
I, D
Port 0 Carrier Sense and Data Valid
20
M0_TXD
O
Port 0 Transmit Data
21
M0_TXCLK
I
Port 0 Transmit Clock
19
M0_TXEN
O
Port 0 Transmit Enable
12
M0_CLS
I, U
Port 0 Collision Detection
13
M0_LINK
I, U
Port 0 Link Status
14
M0_DUPLEX
I, U
Port 0 Full Duplex Select (half-duplex = 0)
30
M1_RXD
I, U
Port 1 Receive Data
31
M1_RXCLK
I, U
Port 1 Receive Clock
29
M1_CRS_DV
I, D
Port 1 Carrier Sense and Data Valid
27
M1_TXD
O
Port 1 Transmit Data
28
M1_TXCLK
I
Port 1 Transmit Clock
26
M1_TXEN
O
Port 1 Transmit Enable
15
M1_CLS
I, U
Port 1 Collision Detection
16
M1_LINK
I, U
Port 1 Link Status
17
M1_DUPLEX
I, U
Port 1 Full-Duplex Select (half-duplex = 0)
37
M2_RXD
I, U
Port 2 Receive Data
38
M2_RXCLK
I, U
Port 2 Receive Clock
36
M2_CRS_DV
I, D
Port 2 Carrier Sense and Data Valid
34
M2_TXD
O
Port 2 Transmit Data
35
M2_TXCLK
I
Port 2 Transmit Clock
33
M2_TXEN
O
Port 2 Transmit Enable
47
M2_CLS
I, U
Port 2 Collision Detection
48
M2_LINK
I, U
Port 2 Link Status
49
M2_DUPLEX
I, U‘
Port 2 Full-Duplex Select (half-duplex = 0)
M3_RXD
I, U
Port 3 Receive Data
Port 1 Serial Interface
Port 2 Serial Interface
Port 3 Serial Interface
44
25
Zarlink Semiconductor Inc.
MVTX1100
Pin No(s).
Symbol
Data Sheet
Type
Name & Functions
45
M3_RXCLK
I, U
Port 3 Receive Clock
43
M3_CRS_DV
I, D
Port 3 Carrier Sense and Data Valid
41
M3_TXD
O
Port 3 Transmit Data
42
M3_TXCLK
I
Port 3 Transmit Clock
40
M3_TXEN
O
Port 3 Transmit Enable
50
M3_CLS
I, U
Port 3 Collision Detection
51
M3_LINK
I, U
Port 3 Link Status
52
M3_DUPLEX
I, u
Port 3 Full-Duplex Select (half-duplex = 0)
64
M4_RXD
I, U
Port 4 Receive Data
65
M4_RXCLK
I, U
Port 4 Receive Clock
63
M4_CRS_DV
I, U
Port 4 Carrier Sense and Data Valid
61
M4_TXD
O
Port 4 Transmit Data
62
M4_TXCLK
I
Port 4 Transmit Clock
60
M4_TXEN
O
Port 4 Transmit Enable
53
M4_CLS
I, U
Port 4 Collision Detection
54
M4_LINK
I, U
Port 4 Link Status
55
M4_DUPLEX
I, U
Port 4 Full-Duplex Select (half-duplex = 0)
71
M5_RXD
I, U
Port 5 Receive Data
72
M5_RXCLK
I, U
Port 5 Receive Clock
70
M5_CRS_DV
I, D
Port 5 Carrier Sense and Data Valid
68
M5_TXD
O
Port 5 Transmit Data
69
M5_TXCLK
I
Port 5 Transmit Clock
67
M5_TXEN
O
Port 5 Transmit Enable
56
M5_CLS
I, U
Port 5 Collision Detection
57
M5_LINK
I, U
Port 5 Link Status
58
M5_DUPLEX
I, U
Port 5 Full-Duplex Select (half-duplex = 0)
M6_RXD
I, U
Port 6 Receive Data
Port 4 Serial Interface
Port 5 Serial Interface
Port 6 Serial Interface
78
26
Zarlink Semiconductor Inc.
MVTX1100
Pin No(s).
Symbol
Data Sheet
Type
Name & Functions
79
M6_RXCLK
I, U
Port 6 Receive Clock
77
M6_CRS_DV
I, D
Port 6 Carrier Sense and Data Valid
75
M6_TXD
O
Port 6 Transmit Data
76
M6_TXCLK
I
Port 6 Transmit Clock
74
M6_TXEN
O
Port 6 Transmit Enable
88
M6_CLS
I, U
Port 6 Collision Detection
89
M6_LINK
I, U
Port 6 Link Status
90
M6_DUPLEX
I, U
Port 6 Full-Duplex Select (half-duplex = 0)
85
M7_RXD
I, U
Port 7 Receive Data
86
M7_RXCLK
I, U
Port 7 Receive Clock
84
M7_CRS_DV
I, D
Port 7 Carrier Sense and Data Valid
82
M7_TXD
O
Port 7 Transmit Data
83
M7_TXCLK
I
Port 7 Transmit Clock
81
M7_TXEN
O
Port 7 Transmit Enable
91
M7_CLS
U
Port 7 Collision Detection
92
M7_LINK
I, U
Port 7 Link Status
93
M7_DUPLEX
I, U
Port 7 Full-Duplex Select (half-duplex = 0)
24, 23
M0_RXD[1:0]
I, U
Port 0 Receive Data
22
M0_CRS_DV
I, D
Port 0 Carrier Sense and Data Valid
21, 20
M0_TXD[1:0]
O
Port 0 Transmit Data
19
M0_TXEN
O
Port 0 Transmit Enable
31, 30
M1_RXD[1:0]
I, U
Port 1 Receive Data
29
M1_CRS_DV
I, D
Port 1 Carrier Sense and Data Valid
28, 27
M1_TXD[1:0]
O
Port 1 Transmit Data
26
M1_TXEN
O
Port 1 Transmit Enable
M2_RXD[1:0]
I, U
Port 2 Receive Data
Port 7 Serial Interface
Port 0 RMII Interface
Port 1 RMII Interface
Port 2 RMII Interface
38, 27
27
Zarlink Semiconductor Inc.
MVTX1100
Pin No(s).
Symbol
Data Sheet
Type
Name & Functions
36
M2_CRS_DV
I, D
Port 2 Carrier Sense and Data Valid
35, 34
M2_TXD[1:0]
O
Port 2 Transmit Data
34
M2_TXEN
O
Port 2 Transmit Enable
45, 44
M3_RXD[1:0]
I, U
Port 3 Receive Data
43
M3_CRS_DV
I, D
Port 3 Carrier Sense and Data Valid
42, 41
M3_TXD[1:0]
O
Port 3 Transmit Data
40
M3_TXEN
O
Port 3 Transmit Enable
65, 64
M4_RXD[1:0]
I, U
Port 4 Receive Data
63
M4_CRS_DV
I, D
Port 4 Carrier Sense and Data Valid
62, 61
M4_TXD[1:0]
O
Port 4 Transmit Data
60
M4_TXEN
O
Port 4 Transmit Enable
72, 71
M5_RXD[1:0]
I, U
Port 5 Receive Data
70
M5_CRS_DV
I, D
Port 5 Carrier Sense and Data Valid
69, 68
M5_TXD[1:0]
O
Port 5 Transmit Data
67
M5_TXEN
O
Port 5 Transmit Enable
79, 78
M6_RXD[1:0]
I, U
Port 6 Receive Data
77
M6_CRS_DV
I, D
Port 6 Carrier Sense and Data Valid
76, 75
M6_TXD[1:0]
O
Port 6 Transmit Data
74
M6_TXEN
O
Port 6 Transmit Enable
86, 85
M7_RXD[1:0]
I, U
Port7 Receive Data
84
M7_CRS_DV
I, D
Port 7 Carrier Sense and Data Valid
83, 82
M7_TXD[1:0]
O
Port 7 Transmit Data
81
M7_TXEN
O
Port 7 Transmit Enable
M8_RXD[3:0]
I, U
Port 8 Receive Data
Port 3 RMII Interface
Port 4 RMII Interface
Port 5 RMII Interface
Port 6 RMII Interface
Port 7 RMII Interface
Port 8 MII Interface
105, 104, 103, 102
28
Zarlink Semiconductor Inc.
MVTX1100
Pin No(s).
Symbol
Data Sheet
Type
Name & Functions
113, 112, 111, 110
M8_TXD[3:0]
O
Port 8 Transmit Data
109
M8_TXEN
O
Port 8 Transmit Enable
97
M8_RXDV
I, D
Port 8 Receive Data Valid
100
M8_RXCLK
I, U
Port 8 Receive Clock
107
M8_TXCLK
I/O, U
Port 8 Transmit Clock
114
M8_LINK
I, U
Port 8 Link Status
116
M8_SPEED
I/O, U
Port 8 Speed Select (100Mb = 1)
115
M8_DUPLEX
I, U
Port 8 Full-Duplex Select (half-duplex = 0)
98
M8_COL
I, U
Port 8 Collision Detect
118
M8_REFCLK
O, U
Port 8 Reference Clock
M8_REFCLK=1/2 M_CLK
102
S8_RXD
I, U
Port 8 Serial Receive Data
100
S8_RXCLK
I, U
Port 8 Serial Receive Clock
97
S8_CRS_DV
I, D
Port 8 Serial Carrier Sense and Data Valid
110
S8_TXD
O
Port 8 Serial Transmit Data
107
S8_TXCLK
I
Port 8 Serial Transmit Clock
109
S8_TXEN
O
Port 8 Serial Transmit Enable
98
S8_COL
I, U
Port 8 Serial Collision Detect
114
S8_LINK
I, U
Port 8 Link Status
115
S8_DUPLEX
I, U
Port 8 Full-Duplex Select (half-duplex = 0)
95
M_CLK
I
Reference Clock for Serial interface =
50 MHz±50 ppm
148
SCLK
I
System Clock (50 - 80 MHz)
126
TRUNK_EN
I, D
Port Trunking Enable
142
RESIN#
I, S
Reset Pin
141
RESETOUT#
O
PHY Reset Pin
146, 145, 144, 143
MIR_CTL[3:0]
I/O, U
Port Mirroring Control (only for RMII mode)
Port 8 Serial Interface
Miscellaneous Control Pins
29
Zarlink Semiconductor Inc.
MVTX1100
Pin No(s).
Symbol
Data Sheet
Type
Name & Functions
Test Pins
125
TEST#
Manufacturing Pin.
Leave as No Connect (NC)
139
TMODE#
I/O, U
Manufacturing Pin. Puts device into test mode
for ATE test.
Leave as No Connect (NC)
138, 137, 136, 135
TSTOUT[7:4]
O
Test Outputs
134, 133, 132, 131
TSTOUT[3:0]
I/O, U
Test Outputs
VDD (Core)
Input
+3.3 Volt DC Supply for Core Logic (7 pins)
11, 25, 59, 87, 101, 108, 119, VDD
147, 152, 166, 175, 194, 202
Input
+3.3 Volt DC Supply for I/O Pads (13 pins)
18, 46, 80, 106, 140, 171,
198
Input
Ground for Core Logic (7 pins)
Input
Ground for I/O Pads (13 pins)
Power Pins
3, 39, 73, 96, 130, 159, 184
VSS (Core)
7, 32, 66, 94, 99, 117, 121,
VSS
149, 154, 162, 180, 189, 207
30
Zarlink Semiconductor Inc.
MVTX1100
13.1
Data Sheet
STRAP Options
The Strap options are relevant during the initial power-on period, when reset is asserted. During reset, MVTX1100
will examine the boot strap address pin to determine its value and modify the internal configuration of the chip
accordingly.
“1” means Pull Up
“0” means Pull Down with an external 1 K Ohm
Default value is 1, (all boot strap pins have internal pull up resistor).
Pin No(s)
Symbol
Name & Functions
206 (L_A[5])
Memory Size
1 - Memory size = 256 KB,
0 - Memory size = 512 KB
208 (L_A [6])
EEPROM
1 - NO EEPROM Installed
0 - EEPROM Installed1
1 (L_A [7])
MII Management
via MDIO
1 - Enable
0 - Disable
5, 4 (L_A [10:9])
XLINK Speed
11 - 100 Mbps
10 - 200 Mbps
01 - 300 Mbps
00 - 400 Mbps (0 - Pull down, 1 - Pull up)
160 (L_A[15])
Ports 0-7 RMII/Serial
1 - RMII Mode for ports 0-7
0 - Serial mode for ports 0-7
151 (L_A[17])
Port 8 MII/Serial
1 - MII Mode for port 8
0 - Serial mode for port 8
150 (L_A[2])
Link Polarity
Link Polarity for serial interface
1 - Active Low
0 - Active High
204 (L_A[3])
FDX Polarity
Full/Half Duplex Polarity for serial interface
1 - Active Low
0 - Active High
205 (L_A[4])
SPD100 Polarity
Speed polarity for serial interface
1 - Active Low
0 - Active High
2 (L_A[8])
Device ID
Use in cascade mode only
133 (TST[2])
SBRAM Self Test
For Board/System Manufacturing Test2
1 - Disable
0 - Enable
Note 1:
1. If the MVTX1100 is configured from EEPROM preset (L_A[6] pulled down at reset), it will try to load its configuration from
the EEPROM. If the EEPROM is blank or not preset, it will not boot up. The parallel port can be used to program the EEPROM
at any time.
Note 2:
During normal power-up the MVTX1100 will run through an external SBRAM memory test to ensure that there are no memory
interface problems. If a problem is detected, the chip will stop functioning. To facilitate board debug in the event that a system
stops functioning, the MVTX1100 can be put into a continuous SBRAM self test mode to allow an operator to determine if
there are stuck pins in the memory interface (using network analyzer).
31
Zarlink Semiconductor Inc.
MVTX1100
14.0
DC Electrical Characteristics
14.1
Absolute Maximum Ratings
Data Sheet
Storage Temperature
-65°C to +150C
Operating Temperature
-40°C to +85C
Maximum Junction Temperature
+125C
Supply Voltage VDD with Respect to VSS
+3.0 V to +3.6 V
Voltage on 5V Tolerant Input Pins
-0.5 V to (VDD + 3.3 V)
Voltage on Other Pins
-0.5 V to (VDD + 0.3 V)
Caution: Stresses above those listed may cause permanent device failure. Functionality at or above these limits is
not implied. Exposure to the Absolute Maximum Ratings for extended periods may affect device reliability.
14.2
DC Electrical Characteristics
VDD = 3.0 V to 3.6 V (3.3v +/- 10%) TAMBIENT = -40C to +85C
14.3
Recommended Operating Conditions
Symbol
Parameter Description
fOSC
Frequency of Operation
IDD
VOH
VOL
Supply Current - @ 55 MHz, 8x100 M, 100%
Full Duplex Traffic (VDD = 3.3V)
Output High Voltage (CMOS)
Min.
Typ.
Max.
Unit
50
66
80
MHz
580
mA
2.4
Output Low Voltage (CMOS)
0.4
V
VDD +
2.0
V
VIH-TTL
Input High Voltage (TTL 5 V tolerant)
VIL-TTL
Input Low Voltage (TTL 5 V tolerant)
0.8
V
IIL
Input Leakage Current (0.1 V < VIN < VDD)
(all pins except those with internal pull-up/ pulldown resistors)
10
µA
IOL
Output Leakage Current (0.1 V < VOUT <
VDD)
10
µA
CIN
Input Capacitance
5
pF
Output Capacitance
5
pF
I/O Capacitance
7
pF
COUT
CI/O
2.0
V
θja
Thermal resistance with 0 air flow
29.7
C/W
θja
Thermal resistance with 1 m/s air flow
28.8
C/W
θja
Thermal resistance with 2 m/s air flow
26.8
C/W
θjc
Thermal resistance between junction and case
12.6
C/W
32
Zarlink Semiconductor Inc.
MVTX1100
14.4
Data Sheet
Clock Frequency Specifications
Symbol
Parameter
(Hz)
C1
SCLK - Core System Clock Input
50 M
C2
M_CLK - RMII Port Clock
50 M
C3
M8_REFCLK - MII Reference Clock
25 M
C4
L_CLK - Frame Buffer Memory Clock
50 M
C5
M_MDC - MII Management Data Clock
2
C6
SCL - I C Data Clock
Note:
L_CLK = SCLK
1.56 M
M_MDC = SCLK/32
50 K
SCL = M_CLK/1000
Suggestion Clock rate for various configurations:
Input
Configuration
Port 0-7
Port 8
Output
SCLK
M_CLK
(RMII)
M8_REF
L_CLK
M_MDC
SCL
10 M RMII
10/100 M MII
50 M
50 M
--
=SCLK
=SCLK/32
50 K
100 M RMII
Not Used
55 M
50 M
--
=SCLK
=SCLK/32
50 K
100 M RMII
10/100 M MII
60 M
50 M
--
=SCLK
=SCLK/32
50 K
100 M RMII
200 M MII
66.66 M
50 M
50 M
=SCLK
=SCLK/32
50 K
100 M RMII
300 M MII
75 M
50 M
75 M
=SCLK
=SCLK/32
50 K
100 M RMII
400 M MII
80 M
50 M
100 M
=SCLK
=SCLK/32
50 K
33
Zarlink Semiconductor Inc.
MVTX1100
15.0
AC Timing Characteristics
15.1
Frame Buffer Memory Interface:
Data Sheet
L_D[31:0]
Figure 6 - Framer Buffer Memory Interface Timing
Symbol
50 MHz
Parameter
Min. (ns)
Max. (ns)
Note
L1
L_D[31:0] input setup time
5
L2
L_D[31:0] input hold time
0
L3
L_D[31:0] output valid delay
1
8
CL = 30 pF
L4
L_A[18:2] output valid delay
1
8
CL = 50 pF
L6
L_ADSC# output valid delay
1
8
CL = 50 pF
L8
L_WE# output valid delay
1
8
CL = 30 pF
L9
L_OE# output valid delay
1
8
CL = 30 pF
Table 3 - Frame Buffer Memory Interface Timing
34
Zarlink Semiconductor Inc.
MVTX1100
15.2
Data Sheet
Serial Timing Requirements
Symbol
50 MHz
Parameter
Min. (ns)
Max. (ns)
Note:
M1
M_[8:0]_[TX/RX]CLK
Serial Input Clock
M2
M[8:0]_RXD input setup time
4
M3
M[8:0]_RXD input hold time
1
M4
M[8:0]_CRS_DV input setup time
4
M5
M[8:0]_TXEN output delay time
1
11
CL = 30 pF
M6
M[8:0]_TXD output delay time
1
11
CL = 30 pF
M7
M[8:0]_LINK input setup time
4
Table 4 - Serial Timing Requirements
15.3
RMII Timing Requirements
Symbol
50 MHz
Parameter
Min. (ns)
Max. (ns)
Note:
M1
M_CLK
Reference Input Clock
M2
M[7:0]_RXD[1:0] input setup time
4
M3
M[7:0]_RXD[1:0] input hold time
1
M4
M[7:0]_CRS_DV input setup time
4
M5
M[7:0]_TXEN output delay time
1
11
CL = 30 pF
M6
M[7:0]_TXD[1:0] output delay time
1
11
CL = 30 pF
M7
M[7:0]_LINK input setup time
4
Table 5 - RMII Timing Requirements
35
Zarlink Semiconductor Inc.
MVTX1100
15.4
Data Sheet
MII Timing Requirements
Figure 7 - Transmit Timing
Symbol
Time
Parameter
Min.
Max.
Unit
1
M8_TXCLK rise to M8_TXD[3:0] inactive delay
5
20
ns
2
M8_TXCLK rise to M8_TXD[3:0] active delay
5
20
ns
3
M8_TXCLK rise to M8_TXEN active delay
5
20
ns
4
M8_TXCLK rise of last M8_TXD bit to
M8_TXEN inactive delay
5
20
ns
5
M8_TXCLK high wide
25
Inf.
ns
6
M8_TXCLK low wide
25
Inf.
ns
M8_TXCLK input rise time require
5
ns
M8_TXCLK input fall time require
5
ns
*Inf. = infinite
Table 6 - Transmit Timing Requirements
36
Zarlink Semiconductor Inc.
MVTX1100
Data Sheet
Figure 8 - Receive Timing
Symbol
Time
Parameter
Min.
1
M8_RXD[3:0] low input setup time
2
M8_RXD[3:0] low input hold time
3
M8_RXD[3:0] high input setup time
4
M8_RXD[3:0] high input hold time
5
M8_RXDV low input setup time
6
M8_RXDV low input hold time
7
M8_RXDV high input setup time
8
M8_RXDV high input hold time
9
M8_RXCLK high wide
10
M8_RXCLK low wide
Max.
10
Unit
ns
5
10
ns
ns
5
10
ns
ns
5
10
ns
ns
5
ns
25
Inf.
ns
25
Inf.
ns
M8_RXCLK input rise time require
5
ns
M8_RXCLK input fall time require
5
ns
Table 7 - Receive Timing Requirements
37
Zarlink Semiconductor Inc.
D
D1
= 0°-7°
A
E1
A2
E
A1
L
INDEX CORNER
PIN 1
Notes:
1. Pin 1 indicator may be a corner chamfer, dot or both.
2. Controlling dimensions are in millimeters.
3. The top package body size may be smaller than the bottom package body size by a max. of 0.15 mm.
4. Dimension D1 and E1 do not include mould protusion.
Package Code
c Zarlink Semiconductor 2003 All rights reserved.
ISSUE
ACN
DATE
APPRD.
Previous package codes:
For more information about all Zarlink products
visit our Web Site at
www.zarlink.com
Information relating to products and services furnished herein by Zarlink Semiconductor Inc. or its subsidiaries (collectively “Zarlink”) is believed to be reliable.
However, Zarlink assumes no liability for errors that may appear in this publication, or for liability otherwise arising from the application or use of any such
information, product or service or for any infringement of patents or other intellectual property rights owned by third parties which may result from such application or
use. Neither the supply of such information or purchase of product or service conveys any license, either express or implied, under patents or other intellectual
property rights owned by Zarlink or licensed from third parties by Zarlink, whatsoever. Purchasers of products are also hereby notified that the use of product in
certain ways or in combination with Zarlink, or non-Zarlink furnished goods or services may infringe patents or other intellectual property rights owned by Zarlink.
This publication is issued to provide information only and (unless agreed by Zarlink in writing) may not be used, applied or reproduced for any purpose nor form part
of any order or contract nor to be regarded as a representation relating to the products or services concerned. The products, their specifications, services and other
information appearing in this publication are subject to change by Zarlink without notice. No warranty or guarantee express or implied is made regarding the
capability, performance or suitability of any product or service. Information concerning possible methods of use is provided as a guide only and does not constitute
any guarantee that such methods of use will be satisfactory in a specific piece of equipment. It is the user’s responsibility to fully determine the performance and
suitability of any equipment using such information and to ensure that any publication or data used is up to date and has not been superseded. Manufacturing does
not necessarily include testing of all functions or parameters. These products are not suitable for use in any medical products whose failure to perform may result in
significant injury or death to the user. All products and materials are sold and services provided subject to Zarlink’s conditions of sale which are available on request.
Purchase of Zarlink’s I2C components conveys a licence under the Philips I2C Patent rights to use these components in and I2C System, provided that the system
conforms to the I2C Standard Specification as defined by Philips.
Zarlink, ZL and the Zarlink Semiconductor logo are trademarks of Zarlink Semiconductor Inc.
Copyright Zarlink Semiconductor Inc. All Rights Reserved.
TECHNICAL DOCUMENTATION - NOT FOR RESALE