W5500 Datasheet
Version 1.0.9
http://www.wiznet.co.kr
© Copyright 2013 WIZnet Co., Ltd. All rights reserved.
W5500
The W5500 chip is a Hardwired TCP/IP embedded Ethernet controller that provides
easier Internet connection to embedded systems. W5500 enables users to have the
Internet connectivity in their applications just by using the single chip in which TCP/IP
stack, 10/100 Ethernet MAC and PHY embedded.
WIZnet‘s Hardwired TCP/IP is the market-proven technology that supports TCP, UDP,
IPv4, ICMP, ARP, IGMP, and PPPoE protocols. W5500 embeds the 32Kbyte internal
memory buffer for the Ethernet packet processing. If you use W5500, you can
implement the Ethernet application just by adding the simple socket program. It’s
faster and easier way rather than using any other Embedded Ethernet solution. Users
can use 8 independent hardware sockets simultaneously.
SPI (Serial Peripheral Interface) is provided for easy integration with the external
MCU. The W5500’s SPI supports 80 MHz speed and new efficient SPI protocol for the
high speed network communication. In order to reduce power consumption of the
system, W5500 provides WOL (Wake on LAN) and power down mode.
Features
2 / 66
-
Supports Hardwired TCP/IP Protocols : TCP, UDP, ICMP, IPv4, ARP, IGMP, PPPoE
-
Supports 8 independent sockets simultaneously
-
Supports Power down mode
-
Supports Wake on LAN over UDP
-
Supports High Speed Serial Peripheral Interface(SPI MODE 0, 3)
-
Internal 32Kbytes Memory for TX/RX Buffers
-
10BaseT/100BaseTX Ethernet PHY embedded
-
Supports Auto Negotiation (Full and half duplex, 10 and 100-based )
-
Not supports IP Fragmentation
-
3.3V operation with 5V I/O signal tolerance
-
LED outputs (Full/Half duplex, Link, Speed, Active)
-
48 Pin LQFP Lead-Free Package (7x7mm, 0.5mm pitch)
W5500 Datasheet Version1.0.9
Target Applications
W5500 is suitable for the following embedded applications:
- Home Network Devices: Set-Top Boxes, PVRs, Digital Media Adapters
- Serial-to-Ethernet: Access Controls, LED displays, Wireless AP relays, etc.
- Parallel-to-Ethernet: POS / Mini Printers, Copiers
- USB-to-Ethernet: Storage Devices, Network Printers
- GPIO-to-Ethernet: Home Network Sensors
- Security Systems: DVRs, Network Cameras, Kiosks
- Factory and Building Automations
- Medical Monitoring Equipment
- Embedded Servers
W5500 Datasheet Version1.0.9
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Block Diagram
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W5500 Datasheet Version1.0.9
Table of Contents
Pin Assignment .......................................................................................... 7
1.1
Pin Descriptions .............................................................................. 7
HOST Interface ......................................................................................... 12
2.1
SPI Operation Mode ........................................................................ 13
2.2
SPI Frame .................................................................................... 14
2.3
2.4
2.2.1
Address Phase......................................................................... 14
2.2.2
Control Phase ......................................................................... 15
2.2.3
Data Phase ............................................................................ 17
Variable Length Data Mode (VDM) ....................................................... 17
2.3.1
Write Access in VDM ................................................................. 18
2.3.2
Read Access in VDM .................................................................. 21
Fixed Length Data Mode (FDM) .......................................................... 24
2.4.1
Write Access in FDM ................................................................. 25
2.4.2
Read Access in FDM .................................................................. 26
Register and Memory Organization ................................................................ 27
3.1
Common Register Block ................................................................... 29
3.2
Socket Register Block ...................................................................... 30
3.3
Memory ...................................................................................... 31
Register Descriptions ................................................................................. 32
4.1
Common Registers ......................................................................... 32
4.2
Socket Registers ............................................................................ 44
Electrical Specifications ............................................................................. 58
5.1
Absolute Maximum Ratings ............................................................... 58
5.2
Absolute Maximum Ratings (Electrical Sensitivity) ................................... 58
5.3
DC Characteristics ......................................................................... 59
5.4
Power Dissipation .......................................................................... 60
5.5
AC Characteristics ......................................................................... 60
5.5.1
Reset Timing .......................................................................... 60
5.5.2
Wake up Time ......................................................................... 60
5.5.3
Crystal Characteristics .............................................................. 60
5.5.4
SPI Timing ............................................................................. 61
5.5.5
Transformer Characteristics ........................................................ 62
5.5.6
MDIX .................................................................................... 62
IR Reflow Temperature Profile (Lead-Free) ..................................................... 63
Package Descriptions ................................................................................. 64
Document History Information ....................................................................... 65
W5500 Datasheet Version1.0.9
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Table of Figures
Figure 1. W5500 Pin Layout ....................................................................... 7
Figure 2. External reference resistor ......................................................... 11
Figure 3. Crystal reference schematic ........................................................ 11
Figure 4. Variable Length Data Mode (SCSn controlled by the host) .................... 12
Figure 5. Fixed Length Data Mode (SCSn is always connected by Ground) ............. 12
Figure 6. SPI Mode 0 & 3 ........................................................................ 13
Figure 7. SPI Frame Format ..................................................................... 14
Figure 8. Write SPI Frame in VDM mode ...................................................... 18
Figure 9. SIMR Register Write in VDM Mode .................................................. 19
Figure 10. 5 Byte Data Write at 1th Socket’s TX Buffer Block 0x0040 in VDM mode .. 20
Figure 11. Read SPI Frame in VDM mode ..................................................... 21
Figure 12. S7_SR Read in VDM Mode ........................................................... 22
Figure 13. 5 Byte Data Read at Socket 3 RX Buffer Block 0x0100 in VDM mode ....... 23
Figure 14. 1 Byte Data Write SPI Frame in FDM mode...................................... 25
Figure 15. 2 Bytes Data Write SPI Frame in FDM mode .................................... 25
Figure 16. 4 Bytes Data Write SPI Frame in FDM mode .................................... 25
Figure 17. 1 Byte Data Read SPI Frame in FDM mode ...................................... 26
Figure 18. 2 Bytes Data Read SPI Frame in FDM mode ..................................... 26
Figure 19. 4 Bytes Data Read SPI Frame in FDM mode ..................................... 26
Figure 20. Register & Memory Organization ................................................. 28
Figure 21. INTLEVEL Timing ..................................................................... 34
Figure 22. Reset Timing .......................................................................... 60
Figure 23. SPI Timing ............................................................................. 61
Figure 24. Transformer Type .................................................................... 62
Figure 25. IR Reflow Temperature ............................................................. 63
Figure 26. Package Dimensions ................................................................. 64
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W5500 Datasheet Version1.0.9
AGND
NC
NC
PMODE0
PMODE1
PMODE2
RSVD
RSVD
RSVD
RSVD
RSVD
RSTn
48
47
46
45
44
43
42
41
40
39
38
37
Pin Assignment
TXN
1
36
INTn
TXP
2
35
MOSI
AGND
3
34
MISO
AVDD
4
33
SCLK
RXN
5
32
SCSn
RXP
6
31
XO
DNC
7
30
XI/CLKIN
AVDD
8
29
GND
AGND
9
28
VDD
EXRES1
10
27
ACTLED
AVDD
11
26
DUPLED
NC
12
25
LINKLED
W5500
19
20
21
22
23
24
TOCAP
AVDD
1V2O
RSVD
SPDLED
18
VBG
AGND
17
AVDD
15
AVDD
16
14
AGND
AGND
13
NC
48LQFP
Figure 1. W5500 Pin Layout
1.1
Pin Descriptions
Table 1. Pin Type Notation
Type
Description
I
Input
O
Output
I/O
A
Input / Output
Analog
PWR
3.3V power
GND
Ground
W5500 Datasheet Version1.0.9
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Table 2. W5500 Pin Description
Internal
Pin No
Symbol
1
TXN
-
AO
TXP/TXN Signal Pair
2
TXP
-
AO
The differential data is transmitted to the media on the
Bias1
Type
Description
TXP/TXN signal pair.
3
AGND
-
GND
Analog ground
4
AVDD
-
PWR
Analog 3.3V power
5
RXN
-
AI
RXP/RXN Signal Pair
6
RXP
-
AI
The differential data from the media is received on the
RXP/RXN signal pair.
7
DNC
-
AI/O
Do Not Connect Pin
8
AVDD
-
PWR
Analog 3.3V power
9
AGND
-
GND
Analog ground
10
EXRES1
-
AI/O
External Reference Resistor
It should be connected to an external resistor (12.4KΩ,
1%) needed for biasing of internal analog circuits.
Refer to the ‘External reference resistor’ (Figure.2) for
details.
11
AVDD
12
-
-
NC
13
-
-
NC
14
AGND
-
GND
Analog ground
15
AVDD
-
PWR
Analog 3.3V power
16
AGND
-
GND
Analog ground
17
AVDD
-
PWR
Analog 3.3V power
18
VBG
-
AO
-
PWR
Analog 3.3V power
Band Gap Output Voltage
This pin will be measured as 1.2V at 25℃.
It must be left floating.
19
AGND
-
GND
20
TOCAP
-
AO
Analog ground
External Reference Capacitor
This pin must be connected to a 4.7uF capacitor.
The trace length to capacitor should be short to
stabilize the internal signals.
1
21
AVDD
-
PWR
22
1V2O
-
AO
Analog 3.3V power
1.2V Regulator output voltage
Internal Bias after hardware reset
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W5500 Datasheet Version1.0.9
This pin must be connected to a 10nF capacitor.
This is the output voltage of the internal regulator.
23
RSVD
Pull-down
I
It must be tied to GND.
24
SPDLED
-
O
Speed LED
This shows the Speed status of the connected link.
Low: 100Mbps
High: 10Mbps
25
LINKLED
-
O
Link LED
This shows the Link status.
Low: Link is established
High: Link is not established
26
DUPLED
-
O
Duplex LED
This shows the Duplex status for the connected link.
Low: Full-duplex mode
High: Half-duplex mode
27
ACTLED
-
O
Active LED
This shows that there is Carrier sense (CRS) from the
active Physical Medium Sub-layer (PMD) during TX or RX
activity.
Low: Carrier sense from the active PMD
High: No carrier sense
28
VDD
-
PWR
Digital 3.3V Power
29
GND
-
GND
Digital Ground
30
XI/CLKIN
-
AI
Crystal input / External Clock input
External 25MHz Crystal Input.
This pin can also be connected to single-ended TTL
oscillator (CLKIN). 3.3V clock should be applied for the
External Clock input. If this method is implemented, XO
should be left unconnected.
Refer to the ‘Crystal reference schematic’ (Figure.3) for
details.
31
XO
-
AO
Crystal output
External 25MHz Crystal Output
Note: Float this pin if using an external clock being
driven through XI/CLKIN
32
SCSn
Pull-up
I
Chip Select for SPI bus
This pin can be asserted low to select W5500 in SPI
interface.
Low: selected
W5500 Datasheet Version1.0.9
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High: deselected
33
SCLK
-
I
SPI clock input
This pin is used to receive SPI Clock from SPI master.
34
MISO
-
O
SPI master input slave(W5500) output
When SCSn is Low, this pin outputs SPI data.
When SCSn is High, this pin becomes High Impedance
(logically disconnected).
35
MOSI
-
I
SPI master output slave(W5500) input
36
INTn
-
O
Interrupt output
(Active low)
Low: Interrupt asserted from W5500
High: No interrupt
37
RSTn
Pull-up
I
Reset
(Active low)
RESET should be held low at least 500 us for W5500
reset.
38
RSVD
Pull-down
I
NC
39
RSVD
Pull-down
I
NC
40
RSVD
Pull-down
I
NC
41
RSVD
Pull-down
I
NC
42
RSVD
Pull-down
I
NC
43
PMODE2
Pull-up
I
PHY Operation mode select pins
44
PMODE1
Pull-up
I
These pins determine the network mode. Refer to the
45
PMODE0
Pull-up
I
below table for details.
PMODE [2:0]
Description
2
1
0
0
0
0
10BT Half-duplex, Auto-negotiation disabled
0
0
1
10BT Full-duplex, Auto-negotiation disabled
0
1
0
100BT Half-duplex, Auto-negotiation disabled
0
1
1
100BT Full-duplex, Auto-negotiation disabled
1
0
0
100BT Half-duplex, Auto-negotiation enabled
1
0
1
Not used
1
1
0
Not used
1
1
1
All capable, Auto-negotiation enabled
.
46
-
-
-
NC
47
-
-
-
NC
48
AGND
-
GND
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Analog ground
W5500 Datasheet Version1.0.9
The 12.4KΩ(1%) Resistor should be connected between EXRES1 pin and analog ground (AGND)
as below.
Figure 2. External reference resistor
The crystal reference schematic is shown as below.
Figure 3. Crystal reference schematic
W5500 Datasheet Version1.0.9
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HOST Interface
W5500 provides SPI (Serial Peripheral Interface) Bus Interface with 4 signals (SCSn,
SCLK, MOSI, MISO) for external HOST interface, and operates as a SPI Slave.
The W5500 SPI can be connected to MCU as shown in Figure 4 and Figure 5 according
to its operation mode (Variable Length Data / Fixed Length Data Mode) which will be
explained in Chapter 2.3 and Chapter 2.4.
In Figure 4, SPI Bus can be shared with other SPI Devices. Since the SPI Bus is
dedicated to W5500, SPI Bus cannot be shared with other SPI Devices. It is shown in
Figure 5.
At the Variable Length Data mode (as shown in Figure 4), it is possible to share the
SPI Bus with other SPI devices. However, at the Fixed Length Data mode (as shown in
Figure 5), the SPI Bus is dedicated to W5500 and can’t be shared with other devices.
SPI MASTER
SPI SLAVE
MCU
(External Host)
SCSn
SCLK
MOSI
MISO
W5500
SCSn
SCLK
MOSI
MISO
Figure 4. Variable Length Data Mode (SCSn controlled by the host)
SPI MASTER
SPI SLAVE
MCU
(External Host)
SCSn
SCLK
MOSI
MISO
W5500
SCSn
SCLK
MOSI
MISO
Figure 5. Fixed Length Data Mode (SCSn is always connected by Ground)
The SPI protocol defines four modes for its operation (Mode 0, 1, 2, 3).Each mode
differs according to the SCLK polarity and phase. The only difference between SPI
Mode 0 and SPI Mode 3 is the polarity of the SCLK signal at the inactive state.
With SPI Mode 0 and 3, data is always latched in on the rising edge of SCLK and always
output on the falling edge of SCLK.
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W5500 Datasheet Version1.0.9
The W5500 supports SPI Mode 0 and Mode 3. Both MOSI and MISO signals use transfer
sequence from Most Significant Bit (MSB) to Least Significant Bit (LSB) when MOSI
signal transmits and MISO signal receives. MOSI & MISO signals always transmit or
receive in sequence from the Most Significant Bit (MSB) to Least Significant Bit (LSB).
Sampling
Toggling
Toggling
SCLK
SCLK
MISO/MOSI
MISO/MOSI
Mode 0 : SCLK idle level low
Sampling
Mode 3 : SCLK idle level high
Figure 6. SPI Mode 0 & 3
2.1
SPI Operation Mode
W5500 is controlled by SPI Frame (Refer to the Chapter 2.2 SPI Frame) which
communicates with the External Host. W5500 SPI Frame consists 3 phases, Address
Phase, Control Phase and Data Phase.
Address Phase specifies 16 bits Offset Address for W5500 Register or TX/RX Memory.
Control Phase specifies the block to which Offset (set by Address Phase) belongs, and
specifies Read/Write Access Mode and SPI Operation Mode (Variable Length Data /
Fixed Length Data Mode).
And Data Phase specifies random length (N-bytes, 1 ≤ N) Data or 1 byte, 2 bytes and
4 bytes Data.
If SPI Operation Mode is set as Variable Length Data Mode (VDM), SPI Bus Signal SCSn
must be controlled by the External Host with SPI Frame step.
At the Variable Length Data Mode, SCSn Control Start (Assert (High-to-Low)) informs
W5500 of SPI Frame Start (Address Phase), and SCSn Control End (De-assert (Low-toHigh) informs W5500 of SPI Frame End (Data Phase End of random N byte).
W5500 Datasheet Version1.0.9
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2.2
SPI Frame
W5500 SPI Frame consists of 16bits Offset Address in Address Phase, 8bits Control
Phase and N bytes Data Phase as shown in Figure 7.
The 8bits Control Phase is reconfigured with Block Select bits (BSB[4:0]), Read/Write
Access Mode bit (RWB) and SPI Operation Mode (OM[1:0]).
Block Select bits select the block to which the Offset Address belongs.
Address Phase
Data Phase
N >= 1
Control Phase
MSB first
MSB first
0
1
Bit 15 14 13 12 11 10 9 8
7 6 5 4 3 2 1 0
16btis Offset Address
2
N+2
3
7 6 5 4 3 2 1 0
7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Control Byte
Block
Select Bits
Data
1
...
Data
N
R OP
W Mode
Figure 7. SPI Frame Format
W5500 supports Sequential Data Read/Write. It processes the data from the base
(the Offset Address which is set for 2/4/N byte Sequential data processing) and the
next data by increasing the Offset Address (auto increment addressing) by 1.
2.2.1 Address Phase
This Address Phase specifies the 16 bits Offset Address for the W5500 Registers and
TX/RX Buffer Blocks.
The 16-bit Offset Address value is transferred from MSB to LSB sequentially.
The SPI frame with 2/4/N byte data phase supports the Sequential Data Read/Write in
which Offset address automatically increases by 1 every 1 byte data.
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W5500 Datasheet Version1.0.9
2.2.2
Control Phase
The Control Phase specifies the Block to which the Offset Address (set by Address
Phase) belongs, the Read/Write Access Mode and the SPI Operation Mode.
7
6
5
4
3
2
1
0
BSB4
BSB3
BSB2
BSB1
BSB0
RWB
OM1
OM0
Bit
Symbol
Description
Block Select Bits
W5500 has Common Register, 8 Socket Register, TX/RX Buffer Block for
each Socket.
The next table shows the Block selected by BSB[4:0].
BSB [4:0]
7~3
BSB [4:0]
W5500 Datasheet Version1.0.9
Meaning
00000
Selects Common Register.
00001
Selects Socket 0 Register
00010
Selects Socket 0 TX Buffer
00011
Selects Socket 0 RX Buffer
00100
Reserved
00101
Selects Socket 1 Register
00110
Selects Socket 1 TX Buffer
00111
Selects Socket 1 RX Buffer
01000
Reserved
01001
Selects Socket 2 Register
01010
Selects Socket 2 TX Buffer
01011
Selects Socket 2 RX Buffer
01100
Reserved
01101
Selects Socket 3 Register
01110
Selects Socket 3 TX Buffer
01111
Selects Socket 3 RX Buffer
10000
Reserved
10001
Selects Socket 4 Register
10010
Selects Socket 4 TX Buffer
10011
Selects Socket 4 RX Buffer
10100
Reserved
10101
Selects Socket 5 Register
10110
Selects Socket 5 TX Buffer
10111
Selects Socket 5 RX Buffer
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11000
Reserved
11001
Selects Socket 6 Register
11010
Selects Socket 6 TX Buffer
11011
Selects Socket 6 RX Buffer
11100
Reserved
11101
Selects Socket 7 Register
11110
Selects Socket 7 TX Buffer
11111
Selects Socket 7 RX Buffer
If the Reserved Bits are selected, it can cause the mal-function of the
W5500.
Read/Write Access Mode Bit
This sets Read/Write Access Mode.
2
RWB
‘0’ : Read
‘1’ : Write
SPI Operation Mode Bits
This sets the SPI Operation Mode.
SPI Operation Mode supports two modes, the Variable Length Data Mode
and the Fixed Length Data Mode.
- Variable Length Data Mode (VDM)
: Data Length is controlled by SCSn.
External Host makes SCSn Signal Assert (High-to-Low) and informs
the start of the SPI Frame Address Phase to W5500.
Then the external host transfers the Control Phase with
1~0
OM [1:0]
OM[1:0]=’00’.
After N-Bytes Data Phase transfers, SCSn Signal is De-asserted (Lowto-High) and informs the end of the SPI Frame Data Phase to W5500.
In VDM Mode, the SCSn must be controlled with SPI Frame unit by
the External Host. (Refer to the Figure 4)
- Fixed Length Data Mode (FDM)
: In FDM, the Data Length is set by OM[1:0], these are not ‘00’ value.
So, the SCSn signal should be Low state, and has one Length type
(among 1 Bytes, 2 Bytes, 4 Bytes) according to the OM[1:0] value.
(Refer to the Figure 5.)
The next table shows the SPI Operation Mode according to the OM[1:0].
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W5500 Datasheet Version1.0.9
2.2.3
OM[1:0]
Meaning
00
Variable Data Length Mode, N-Bytes Data Phase (1 ≤ N)
01
Fixed Data Length Mode , 1 Byte Data Length (N = 1)
10
Fixed Data Length Mode , 2 Byte Data Length (N = 2)
11
Fixed Data Length Mode , 4 Byte Data Length (N = 4)
Data Phase
With the Control Phase set by the SPI Operation Mode Bits OM[1:0], the Data Phase
is set by two types of length, one type is the N-Bytes length (VDM mode) and the other
type is 1/2/4 Bytes (FDM mode).
At this time, 1 byte data is transferred through MOSI or MISO signal from MSB to LSB
sequentially.
2.3
Variable Length Data Mode (VDM)
In VDM mode, the SPI Frame Data Phase Length is determined by SCSn Control of the
External Host. That means that the Data Phase Length can have random value (Any
length from 1 Byte to N Bytes) according to the SCSn Control.
The OM[1:0] of the Control Phase should be ‘00’ value in VDM mode.
W5500 Datasheet Version1.0.9
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2.3.1
Write Access in VDM
SPI Frame Start
SCSn shoud be remained low until SPI Frame Transmit done.
SCSn
MODE3
SCLK
0
1
2
12
13
14
15
16
17
18
19 20
21 22
24 25
23
27 28
26
29
30
31
2
1
0
MODE0
16 bits Offset Address
MOSI
15
14
3
13
RWB OM[1:0]
BSB[4:0]
2
1
0
4
3
2
0
1
8-bit Data 1
W 0 0
7
6
5
4
3
MISO
SPI Frame End
SCSn Should be remained low until SPI Frame Transmit done.
SCSn
32
33
34
35
36 37
37
39
1
0
...
8N + 16
8N + 24
SCLK
8-bit Data 2
MOSI
7
6
5
4
3
...
2
7
6
5
4
8-bit Data
3
2
1
0
7
6
5
4
3
N
2
1
0
MISO
Figure 8. Write SPI Frame in VDM mode
Figure 8 shows the SPI Frame when the external host accesses W5500 for
writing.
In VDM mode, the RWB signal is ‘1’ (Write), OM[1:0] is ‘00’ in SPI Frame Control
Phase. At this time the External Host assert (High-to-Low) SCSn signal before
transmitting SPI Frame. Then the Host transmits SPI Frame’s all bits to W5500
through MOSI signal. All bits are synchronized with the falling edge of the SCLK.
After finishing the SPI Frame transmit, the Host deasserts SCSn signal (Low-toHigh).
When SCSn is Low and the Data Phase continues, the Sequential Data Write can be
supported.
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W5500 Datasheet Version1.0.9
1 Byte WRITE Access Example
When the Host writes Data 0xAA to ‘Socket Interrupt Mask Register (SIMR) of Common
Register Block by using VDM mode, the data is written with the SPI Frame below.
Offset Address = 0x0018
BSB[4:0]
= ‘00000’
RWB
= ‘1’
OM[1:0]
= ‘00’
1st
= 0xAA
Data
The External Host asserts (High-to-Low) SCSn before transmitting SPI Frame, then
the Host transmits 1 bit with synchronizing the Toggle SCLK. The External Host deasserts (Low-to-High) the SCSn at the end of SPI Frame transmit. (Refer to the Figure
9)
SCSn
Figure 9. SIMR Register Write in VDM Mode
W5500 Datasheet Version1.0.9
19 / 66
N-Bytes WRITE Access Example
When the Host writes 5 Bytes Data (0x11, 0x22, 0x33, 0x44, 0x55) to Socket 1’s TX
Buffer Block 0x0040 Address by using VDM mode, 5 bytes data are written with the
SPI Frame below.
Offset Address = 0x0040
BSB[4:0]
= ‘00110’
RWB
=
OM[1:0]
= ‘00’
1st
Data
= 0x11
2nd Data
= 0x22
3rd
Data
= 0x33
4th Data
= 0x44
5th
= 0x55
Data
‘1’
The N-Bytes Write Access is shown in Figure 10.
The 5 bytes of Data (0x11, 0x22, 0x33, 0x44, 0x55) are written sequentially to Socket
1’s Tx Buffer Block Address 0x0040 ~ 0x0044.
The External Host asserts (High-to-Low) SCSn before transmitting SPI Frame.
The External Host de-asserts (Low-to-High) the SCSn at the end of SPI Frame transmit.
SCSn
SCSn
Figure 10. 5 Byte Data Write at 1th Socket’s TX Buffer Block 0x0040 in VDM mode
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W5500 Datasheet Version1.0.9
2.3.2
Read Access in VDM
SPI Frame Start
SCSn shoud be remained low until SPI Frame Transmit & Receive done.
SCSn
MODE3
SCLK
0
1
2
12 13
14
16
15
17
18
19 20
21 22
27 28
24 25 26
23
29
30
31
2
1
0
MODE0
MOSI
15
14
3
13
RWB OM[1:0]
BSB[4:0]
16bits Offset Address
2
1
0
4
3
2
0
R
0
1
8-bit Data
1
0
MISO
7
6
5
4
3
SPI Frame End
SCSn Should be remained low until SPI Frame Transmit & Receive done.
SCSn
32
33
34
35
36 37
38
...
39
8N + 16
8N + 24
SCLK
8-bit Data
...
2
8-bit Data
N
MOSI
MISO
7
6
5
4
3
2
1
0
7
6
5
4
3
2
1
0
7
6
5
4
3
2
1
0
Figure 11. Read SPI Frame in VDM mode
Figure 11 shows the SPI Frame when external host accesses W5500 for reading
In VDM mode, the RWB signal is ‘0’ (Write), OM[1:0] is ‘00’ in SPI Frame Control
Phase. At this time the External Host assert (High-to-Low) SCSn signal before
transmitting SPI Frame.
Then the Host transmits Address and Control Phase all bits to W5500 through MOSI
signal. All bits are synchronized with the falling edge of the SCLK.
Then the Host receives all bits of Data Phase with synchronizing the rising edge of
Sampling SCLK through MISO signal.
After finishing the Data Phase receive, the Host de-asserts SCSn signal (Low-toHigh).
When SCSn is Low and the Data Phase continues to receive, the Sequential Data
Read can be supported.
W5500 Datasheet Version1.0.9
21 / 66
1 Byte READ Access Example
When the Host reads the ‘Socket Status Register(S7_SR) of the Socket 7’s Register
Block by using VDM mode, the data is read with the SPI Frame below. Let’s S7_SR to
‘SOCK_ESTABLISHED (0x17)’.
Offset Address = 0x0003
BSB[4:0]
= ‘11101’
RWB
= ‘0’
OM[1:0]
= ‘00’
1st
= 0x17
Data
The External Host asserts (High-to-Low) SCSn signal before transmitting SPI Frame,
then the Host transmits Address and Control Phase to W5500 through the MOSI signal.
Then the Host receives Data Phase from the MISO signal.
After finishing the Data Phase receives, the Host de-asserts SCSn signal (Low-toHigh). (Refer to the Figure 12)
SCSn
Figure 12. S7_SR Read in VDM Mode
22 / 66
W5500 Datasheet Version1.0.9
N-Bytes Read Access Example
When the Host reads 5 Bytes Data (0xAA, 0xBB, 0xCC, 0xDD, 0xEE) from the Socket
3’s RX Buffer Block 0x0100 Address by using VDM mode, 5 bytes data are read with the
SPI Frame as below.
Offset Address = 0x0100
BSB[4:0]
= ‘01111’
RWB
= ‘0’
OM[1:0]
= ‘00’
1st Data
= 0xAA
2nd
Data
= 0xBB
3rd Data
= 0xCC
4th
Data
= 0xDD
5th Data
= 0xEE
The N-Bytes Read Access is shown in Figure 13.
The 5 bytes of Data (0xAA, 0xBB, 0xCC, 0xDD, 0xEE) are read sequentially from the
Socket 3’s Rx Buffer Block Address 0x0100 ~ 0x0104.
The External Host asserts (High-to-Low) SCSn before transmitting SPI Frame.
The External Host de-asserts (Low-to-High) the SCSn at the end of the SPI Frame Data
Phase.
SCSn
SCSn
Figure 13. 5 Byte Data Read at Socket 3 RX Buffer Block 0x0100 in VDM mode
W5500 Datasheet Version1.0.9
23 / 66
2.4
Fixed Length Data Mode (FDM)
The FDM mode can be used when the External Host cannot control SCSn signal.
The SCSn signal should be tied to Low (Always connected to GND) and it is not possible
to share the SPI Bus with other SPI Devices. (Refer to the Figure 5)
In VDM mode, Data Phase length is controlled by SCSn control.
But in FDM mode, Data Phase length is controlled by OM[1:0] value (‘01’ / ‘10’ / ‘11’)
which is the SPI Operation Mode Bits of the Control Phase.
As the SPI Frame of FDM mode is the same as SPI Frame of VDM mode (1Byte, 2 Bytes,
4 Bytes SPI Frame) except for the SCSn signal control and OM[1:0] setting, the detail
about FDM mode is not described in this section.
It is not recommended to use the FDM mode unless you are in inevitable status. In
addition, we use only 1/2/4 Bytes SPI Frame, as described in ‘Chapter 2.4.1’ & ‘Chapter
2.4.2’. Using SPI Frame with other length of Data will cause malfunction of W5500.
24 / 66
W5500 Datasheet Version1.0.9
2.4.1
Write Access in FDM
1 Bytes WRITE Access
Figure 14. 1 Byte Data Write SPI Frame in FDM mode
2 Bytes WRITE Access
Figure 15. 2 Bytes Data Write SPI Frame in FDM mode
4 Bytes WRITE Access
Figure 16. 4 Bytes Data Write SPI Frame in FDM mode
W5500 Datasheet Version1.0.9
25 / 66
2.4.2
Read Access in FDM
1 Byte READ Access
Figure 17. 1 Byte Data Read SPI Frame in FDM mode
2 Bytes READ Access
Figure 18. 2 Bytes Data Read SPI Frame in FDM mode
4 Bytes READ Access
Figure 19. 4 Bytes Data Read SPI Frame in FDM mode
26 / 66
W5500 Datasheet Version1.0.9
Register and Memory Organization
W5500 has one Common Register Block, eight Socket Register Blocks, and TX/RX
Buffer Blocks allocated to each Socket. Each block is selected by the BSB[4:0](Block
Select Bit) of SPI Frame.
Figure 20 shows the selected block by the BSB[4:0] and the available offset address
range of Socket TX/RX Buffer Blocks. Each Socket’s TX Buffer Block exists in one 16KB
TX memory physically and is initially allocated with 2KB.
Also, Each Socket’s RX Buffer Block exists in one 16KB RX Memory physically and is
initially allocated with 2KB.
Regardless of the allocated size of each Socket TX/RX Buffer, it can be accessible
within the 16 bits offset address range (From 0x0000 to 0xFFFF).
Refer to ‘Chapter 3.3’ for more information about 16KB TX/RX Memory organization
and access method.
W5500 Datasheet Version1.0.9
27 / 66
Block Select Bits
16bit Offset Address
Valid Range
Blocks
11111 (0x1F) Socket 7 RX Buffer
11110 (0x1E) Socket 7 TX Buffer
11101 (0x1E) Socket 7 Register
0xFFFF
0x3FFF
0x3E2C
0xF800
0xF7FF
0x3800
0xF000
0xEFFF
0x3000
...
...
11100 (0x1C) Reserved
Physical
16KB RX Memory
11011 (0x1B) Socket 6 RX Buffer
Socket 7 RX Buffer
11010 (0x1A) Socket 6 TX Buffer
0x2000
...
11001 (0x19) Socket 6 Register
0x9E2C
0x2800
0x1800
0x1000
0x0FFF
11000 (0x18) Reserved
10111 (0x17) Socket 5 RX Buffer
0x1000
0x0FFF
0x0800
0x07FF
10110 (0x16) Socket 5 TX Buffer
0x0800
0x0000
10101 (0x15) Socket 5 Register
0x0000
Socket 7
RX Buffer (2KB)
Socket 6
RX Buffer (2KB)
Socket 5
RX Buffer (2KB)
Socket 4
RX Buffer (2KB)
Socket 3
RX Buffer (2KB)
Socket 2
RX Buffer (2KB)
Socket 1
RX Buffer (2KB)
Socket 0
RX Buffer (2KB)
10100 (0x14) Reserved
...
10011 (0x13) Socket 4 RX Buffer
Physical
16KB TX Memory
10010 (0x12) Socket 4 TX Buffer
10001 (0x11) Socket 4 Register
0x3FFF
0xFFFF
01000 (0x10) Reserved
0x3800
0xF800
0xF7FF
01111 (0x0F) Socket 3 RX Buffer
0x3000
01110 (0x0E) Socket 3 TX Buffer
...
01101 (0x0D) Socket 3 Register
0xF000
0xEFFF
0x2800
Socket 1 TX Buffer
01010 (0x0A) Socket 2 TX Buffer
0x413C
...
01011 (0x0B) Socket 2 RX Buffer
...
01100 (0x0C) Reserved
0x2000
0x1800
0x1000
0x0FFF
01001 (0x09) Socket 2 Register
0x1000
0x0FFF
01000 (0x08) Reserved
0x0800
0x07FF
0x093C
0x0800
00111 (0x07) Socket 1 RX Buffer
00101 (0x05) Socket 1 Register
0x0000
...
00110 (0x06) Socket 1 TX Buffer
0x0000
Socket 7
TX Buffer (2KB)
Socket 6
TX Buffer (2KB)
Socket 5
TX Buffer (2KB)
Socket 4
TX Buffer (2KB)
Socket 3
TX Buffer (2KB)
Socket 2
TX Buffer (2KB)
Socket 1
TX Buffer (2KB)
Socket 0
TX Bufer (2KB)
0xFFFF
00100 (0x04) Reserved
00011 (0x03) Socket 0 RX Buffer
Reserved
0x0031
0x0030
Socket 0 Register
0x0000
00010 (0x02) Socket 0 TX Buffer
0xFFFF
00001 (0x01) Socket 0 Register
00000 (0x00) Common Register
Reserved
0x003A
0x0039
Common Register
0x0000
Figure 20. Register & Memory Organization
28 / 66
W5500 Datasheet Version1.0.9
3.1
Common Register Block
Common Register Block configures the general information of W5500 such as IP and
MAC address. This block can be selected by the BSB[4:0] value of SPI Frame. Table 3
defines the offset address of registers in this block. Refer to ‘Chapter 4.1’ for more
details about each register.
Table 3. Offset Address for Common Register
Offset
Register
Offset
Mode
0x0000
Register
Offset
Register
Interrupt Low Level Timer
0x0021
(PHAR3)
(MR)
0x0013
(INTLEVEL0)
0x0022
(PHAR4)
Gateway Address
0x0014
(INTLEVEL1)
0x0023
(PHAR5)
0x0001
(GAR0)
0x0002
(GAR1)
0x0003
(GAR2)
0x0004
(GAR3)
Interrupt
0x0015
0x0016
Subnet Mask Address
0x0005
(SUBR0)
0x0006
(SUBR1)
0x0007
(SUBR2)
0x0008
(SUBR3)
0x0017
PPP Session Identification
(IR)
0x0024
(PSID0)
Interrupt Mask
0x0025
(PSID1)
(IMR)
PPP Maximum Segment Size
Socket Interrupt
0x0026
(PMRU0)
(SIR)
0x0027
(PMRU1)
Socket Interrupt Mask
0x0018
Unreachable IP address
(SIMR)
0x0028
(UIPR0)
Retry Time
0x0029
(UIPR1)
Source Hardware Address
0x0019
(RTR0)
0x002A
(UIPR2)
0x0009
(SHAR0)
0x001A
(RTR1)
0x002B
(UIPR3)
0x000A
(SHAR1)
0x000B
(SHAR2)
0x000C
(SHAR3)
0x000D
(SHAR4)
0x000E
(SHAR5)
Source IP Address
Retry Count
0x001B
0x001C
0x001D
(RCR)
0x002C
(UPORTR0)
PPP LCP Request Timer
0x002D
(UPORTR1)
(PTIMER)
0x002E
(PMAGIC)
0x002F
(SIPR0)
0x0010
(SIPR1)
0x001E
(PHAR0)
0x0011
(SIPR2)
0x001F
(PHAR1)
0x0012
(SIPR3)
0x0020
(PHAR2)
W5500 Datasheet Version1.0.9
PHY Configuration
PPP LCP Magic number
0x000F
0x003A ~ 0xFFFF
Unreachable Port
PPP Destination MAC Address
~
(PHYCFGR)
Reserved
0x0038
Chip version
0x0039
(VERSIONR)
Reserved
29 / 66
3.2
Socket Register Block
W5500 supports 8 Sockets for communication channel. Each Socket is controlled by
Socket n Register Block(when 0≤n≤7). The n value of Socket n Register can be selected
by BSB[4:0] of SPI Frame. Table 4 defines the 16bits Offset Address of registers in
Socket n Register Block.
Refer to ‘Chapter 4.2’ for more details about each register.
Table 4. Offset Address in Socket n Register Block (0≤n≤7)
Offset
Register
Offset
Socket n Mode
0x0000
Register
Offset
Socket n Destination Port
Socket
0x0010
(Sn_DPORT0)
0x0024
Pointer
Socket n Command (Sn_CR)
0x0011
(Sn_DPORT1)
0x0025
(Sn_TX_WR0)
TX
Write
(Sn_TX_WR1)
Socket n
(Sn_IR)
Socket n RX Received
Maximum Segment Size
0x0026
Size
0x0012
(Sn_MSSR0)
0x0027
(Sn_RX_RSR0)
0x0013
(Sn_MSSR1)
Socket n Interrupt
(Sn_RX_RSR1)
Socket n Status
0x0003
n
(Sn_MR)
0x0001
0x0002
Register
Socket n RX Read Pointer
(Sn_SR)
0x0014
Socket n Source Port
0x0004
(Sn_PORT0)
0x0005
(Sn_PORT1)
Socket
0x0015
n
Destination
0x0016
Reserved
0x0028
(Sn_RX_RD0)
Socket n IP TOS
0x0029
(Sn_RX_RD1)
(Sn_TOS)
Socket
n
Socket n IP TTL
0x002A
Pointer
(Sn_TTL)
0x002B
(Sn_RX_WR0)
RX
Write
(Sn_RX_WR1)
Hardware Address
0x0006
(Sn_DHAR0)
0x0017
0x0007
(Sn_DHAR1)
~
0x0008
(Sn_DHAR2)
0x001D
0x0009
(Sn_DHAR3)
0x000A
(Sn_DHAR4)
0x000B
(Sn_DHAR5)
Socket n Interrupt Mask
Reserved
0x002C
Socket
n
Fragment
Offset in IP header
Socket n Receive Buffer
0x001E
(Sn_IMR)
Size
0x002D
(Sn_FRAG0)
(Sn_RXBUF_SIZE)
0x002E
(Sn_FRAG1)
Socket n
0x001F
Transmit Buffer Size
(Sn_TXBUF_SIZE)
Socket n
Keep alive timer
0x002F
(Sn_KPALVTR)
Reserved
Socket n TX Free Size
Destination IP Address
0x0020
(Sn_TX_FSR0)
0x0030
0x000C
(Sn_DIPR0)
0x0021
(Sn_TX_FSR1)
~
0x000D
(Sn_DIPR1)
0x000E
(Sn_DIPR2)
0x0022
(Sn_TX_RD0)
0x000F
(Sn_DIPR3)
0x0023
(Sn_TX_RD1)
30 / 66
Socket n TX Read Pointer
0xFFFF
W5500 Datasheet Version1.0.9
3.3
Memory
W5500 has one 16KB TX memory for Socket n TX Buffer Blocks and one 16KB RX
memory for Socket n RX buffer Blocks.
16KB TX memory is initially allocated in 2KB size for each Socket TX Buffer Block (2KB
X 8 = 16KB). The initial allocated 2KB size of Socket n TX Buffer can be re-allocated by
using ‘Socket n TX Buffer Size Register (Sn_TXBUF_SIZE)’.
Once all Sn_TXBUF_SIZE registers have been configured, Socket TX Buffer is allocated
with the configured size of 16KB TX Memory and is assigned sequentially from Socket
0 to Socket 7. Its physical memory address is automatically determined in 16KB TX
memory. Therefore, the total sum of Sn_TXBUF_SIZE should be not exceed 16 in case
of error in data transmission.
The 16KB RX memory allocation method is the same as the 16KB TX memory
allocation method. 16KB RX memory is initially allocated into 2KB size for each Socket
RX Buffer Block (2KB X 8 = 16KB). The initial allocated 2KB size of Socket n RX Buffer
can be re-allocated by using ‘Socket n RX Buffer Size Register (Sn_RXBUF_SIZE)’.
When all Sn_RXBUF_SIZE registers have been configured, the Socket RX Buffer is
allocated with the configured size in 16KB RX Memory and is assigned sequentially from
Socket 0 to Socket 7. The physical memory address of the Socket RX Buffer is
automatically determined in 16KB RX memory. Therefore, the total sum of
Sn_RXBUF_SIZE should not exceed 16, data reception error will occur if exceeded.
For 16KB TX/RX memory allocation, refer to Sn_TXBUF_SIZE & Sn_RXBUF_SIZE in
‘Chapter 4.2’.
The Socket n TX Buffer Block allocated in 16KB TX memory is buffer for saving data
to be transmitted by host. The 16bits Offset Address of Socket n TX Buffer Block has
64KB address space ranged from 0x0000 to 0xFFFF, and it is configured with reference
to ‘Socket n TX Write Pointer Register (Sn_TX_WR)’ & ‘Socket n TX Read Pointer
Register(Sn_RX_RD)’. However, the 16bits Offset Address automatically converts into
the physical address to be accessible in 16KB TX memory such as Figure 20. Refer to
‘Chapter 4.2’ for Sn_TX_WR & Sn_TX_RD.
The Socket n RX Buffer Block allocated in 16KB RX memory is buffer for saving the
received data through the Ethernet. The 16bits Offset Address of Socket n RX Buffer
Block has 64KB address space ranged from 0x0000 to 0xFFFF, and it is configured with
reference to ‘Socket n RX RD Pointer Register (Sn_RX_RD)’ & ‘Socket n RX Write Pointer
Register (Sn_RX_WR)’. However, the 16bits Offset Address automatically converts into
the physical address to be accessible in 16KB RX memory such as Figure 20. Refer to
‘Chapter 4.2’ for Sn_RX_RD & Sn_RX_WR.
W5500 Datasheet Version1.0.9
31 / 66
Register Descriptions
4.1
Common Registers
MR (Mode Register) [R/W] [0x0000] [0x00] 2
MR is used for S/W reset, ping block mode and PPPoE mode.
7
6
5
4
3
2
1
0
RST
Reserved
WOL
PB
PPPoE
Reserved
FARP
Reserved
Bit
Symbol
7
RST
6
Reserved
Description
If this bit is ‘1’, All internal registers will be initialized. It will be
automatically cleared as ‘0’ after S/W reset.
Reserved
Wake on LAN
0 : Disable WOL mode
1 : Enable WOL mode
If WOL mode is enabled and the received magic packet over UDP has
5
WOL
been normally processed, the Interrupt PIN (INTn) asserts to low. When
using WOL mode, the UDP Socket should be opened with any source port
number. (Refer to Socket n Mode Register (Sn_MR) for opening Socket.)
Notice: The magic packet over UDP supported by W5500 consists of 6
bytes synchronization stream (‘0xFFFFFFFFFFFF’) and 16 times Target
MAC address stream in UDP payload. The options such like password are
ignored. You can use any UDP source port number for WOL mode.
Ping Block Mode
4
PB
0 : Disable Ping block
1 : Enable Ping block
If the bit is ‘1’, it blocks the response to a ping request.
PPPoE Mode
3
PPPoE
0 : Disable PPPoE mode
1 : Enable PPPoE mode
If you use ADSL, this bit should be ‘1’.
2
Reserved
1
FARP
Reserved
Force ARP
2
Register Notation : [Read/Write/ReadClearWrite1] [Address] [Reset value];
ReadClearWrite1 (RCW1) Software can read as well as clear this bit by writing 1. Writing ‘0’ has no
effect on the bit value.
32 / 66
W5500 Datasheet Version1.0.9
0 : Disable Force ARP mode
1 : Enable Force ARP mode
In Force ARP mode, It forces on sending ARP Request whenever data is
sent.
0
Reserved
Reserved
GAR (Gateway IP Address Register) [R/W] [0x0001 – 0x0004] [0x00]
GAR configures the default gateway address.
Ex) In case of “192.168.0.1”
0x0001
0x0002
0x0003
0x0004
192 (0xC0)
168 (0xA8)
0 (0x00)
1 (0x01)
SUBR (Subnet Mask Register) [R/W] [0x0005 – 0x0008] [0x00]
SUBR configures the subnet mask address.
Ex) In case of “255.255.255.0”
0x0005
0x0006
0x0007
0x0008
255 (0xFF)
255 (0xFF)
255 (0xFF)
0 (0x00)
SHAR (Source Hardware Address Register) [R/W] [0x0009 – 0x000E] [0x00]
SHAR configures the source hardware address.
Ex) In case of “00.08.DC.01.02.03”
0x0009
0x000A
0x000B
0x000C
0x000D
0x000E
0x00
0x08
0xDC
0x01
0x02
0x03
SIPR (Source IP Address Register) [R/W] [0x000F – 0x0012] [0x00]
SIPR configures the source IP address.
Ex) In case of “192.168.0.2”
0x000F
0x0010
0x0011
0x0012
192 (0xC0)
168 (0xA8)
0 (0x00)
2 (0x02)
W5500 Datasheet Version1.0.9
33 / 66
INTLEVEL (Interrupt Low Level Timer Register) [R/W] [0x0013 – 0x0014] [0x0000]
INTLEVEL configures the Interrupt Assert Wait Time (IAWT). When the next interrupt
occurs, Interrupt PIN (INTn ) will assert to low after INTLEVEL time.
𝐼𝐴𝑊𝑇 = (𝐼𝑁𝑇𝐿𝐸𝑉𝐸𝐿 + 1) ×
1
𝑃𝐿𝐿𝑐𝑙𝑘 3
× 4 (when INTLEVEL > 0)
Equation 1 Interrupt Assert Wait Time
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16
PLL_CLK
SIR
0x0000
0x0001
S0_IR
0x00
0x04
S1_IR
0x00
0x0003
0x0002
0x00
b.
0x01
a.
c.
IAWT
d.
INTn
Figure 21. INTLEVEL Timing
a. When Timeout Interrupt of Socket 0 is occurred, S0_IR[3] & SIR[0] bit set as ‘1’ and
then INTn PIN is asserted to low.
b. When the connection interrupt of Socket 1 is occurred before the previous interrupt
processing is not completed, S1_IR[0] & SIR[1] bits set as ‘1’ and INTn PIN is still low.
c. If the host processed the previous interrupt completely by clearing the S0_IR[3] bit,
INTn PIN is de-asserted to high but S1_IR[0] & SIR[1] is still set as ‘1’.
d. Although S1_IR[0] & SIR[1] bit is set as ‘1’, the INTn can’t be asserted to low during
INTLEVEL time. After the INTLEVEL time expires, the INTn will be asserted to low.
3
𝑃𝐿𝐿𝑐𝑙𝑘 is 150MHz
34 / 66
W5500 Datasheet Version1.0.9
IR (Interrupt Register) [R/W] [0x0015] [0x00]
IR indicates the interrupt status. Each bit of IR can be cleared when the host writes
‘1’ value to each bit. If IR is not equal to ‘0x00’, INTn PIN is asserted low until it is
‘0x00’.
7
6
CONFLICT
Bit
UNREACH
5
PPPoE
4
MP
Symbol
3
Reserved
2
Reserved
1
Reserved
0
Reserved
Description
IP Conflict
7
CONFLICT
Bit is set as ‘1’ when own source IP address is same with the sender
IP address in the received ARP request.
Destination unreachable
When receiving the ICMP (Destination port unreachable) packet,
6
UNREACH
this bit is set as ‘1’.
When this bit is ‘1’, Destination Information such as IP address and
Port number may be checked with the corresponding UIPR &
UPORTR.
5
PPPoE
PPPoE Connection Close
When PPPoE is disconnected during PPPoE mode, this bit is set.
Magic Packet
4
MP
When WOL mode is enabled and receives the magic packet over
UDP, this bit is set.
3~0
Reserved
Reserved
W5500 Datasheet Version1.0.9
35 / 66
IMR (Interrupt Mask Register) [R/W][0x0016][0x00]
IMR is used to mask interrupts. Each bit of IMR corresponds to each bit of IR. When
a bit of IMR is ‘1’ and the corresponding bit of IR is ‘1’, an interrupt will be issued. In
other words, if a bit of IMR is ‘0’, an interrupt will not be issued even if the
corresponding bit of IR is ‘1’.
7
6
5
4
3
2
1
0
IM_IR7
IM_IR6
IM_IR5
IM_IR4
Reserved
Reserved
Reserved
Reserved
Bit
Symbol
Description
IP Conflict Interrupt Mask
7
IM_IR7
0: Disable IP Conflict Interrupt
1: Enable IP Conflict Interrupt
Destination unreachable Interrupt Mask
6
IM_IR6
0: Disable Destination unreachable Interrupt
1: Enable Destination unreachable Interrupt
PPPoE Close Interrupt Mask
5
IM_IR5
0: Disable PPPoE Close Interrupt
1: Enable PPPoE Close Interrupt
Magic Packet Interrupt Mask
4
IM_IR4
0: Disable Magic Packet Interrupt
1: Enable Magic Packet Interrupt
3~0
36 / 66
Reserved
Reserved
W5500 Datasheet Version1.0.9
SIR (Socket Interrupt Register) [R/W] [0x0017] [0x00]
SIR indicates the interrupt status of Socket. Each bit of SIR be still ‘1’ until Sn_IR is
cleared by the host. If Sn_IR is not equal to ‘0x00’, the n-th bit of SIR is ‘1’ and INTn
PIN is asserted until SIR is ‘0x00’.
7
6
5
4
3
2
1
0
S7_INT
S6_INT
S5_INT
S4_INT
S3_INT
S2_INT
S1_INT
S0_INT
Bit
Symbol
7
Description
When the interrupt of Socket n occurs, the n-th bit of SIR becomes
~
Sn_INT
‘1’.
0
SIMR (Socket Interrupt Mask Register) [R/W] [0x0018] [0x00]
Each bit of SIMR corresponds to each bit of SIR. When a bit of SIMR is ‘1’ and the
corresponding bit of SIR is ‘1’, Interrupt will be issued. In other words, if a bit of SIMR
is ‘0’, an interrupt will be not issued even if the corresponding bit of SIR is ‘1’.
7
6
5
4
3
2
1
0
S7_IMR
S6_IMR
S5_IMR
S4_IMR
S3_IMR
S2_IMR
S1_IMR
S0_IMR
Bit
Symbol
7
~
0
Description
Socket n(Sn_INT) Interrupt Mask
Sn_IMR
0: Disable Socket n Interrupt
1: Enable Socket n Interrupt
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RTR (Retry Time-value Register) [R/W] [0x0019 – 0x001A] [0x07D0]
RTR configures the retransmission timeout period. The unit of timeout period is
100us and the default of RTR is ‘0x07D0’ or ‘2000’. And so the default timeout period
is 200ms(100us X 2000).
During the time configured by RTR, W5500 waits for the peer response to the packet
that is transmitted by Sn_CR(CONNECT, DISCON, CLOSE, SEND, SEND_MAC, SEND_KEEP
command). If the peer does not respond within the RTR time, W5500 retransmits the
packet or issues timeout.
Ex) When timeout-period is set as 400ms, RTR = (400ms / 1ms) X 10 = 4000(0x0FA0)
0x0019
0x001A
0x0F
0xA0
RCR (Retry Count Register) [R/W] [0x001B] [0x08]
RCR configures the number of time of retransmission. When retransmission occurs
as many as ‘RCR+1’, Timeout interrupt is issued (Sn_IR[TIMEOUT] = ‘1’).
Ex) RCR = 0x0007
0x001B
0x07
The timeout of W5500 can be configurable with RTR and RCR. W5500 has two kind
timeout such as Address Resolution Protocol (ARP) and TCP retransmission.
At the ARP (Refer to RFC 826, http://www.ietf.org/rfc.html) retransmission timeout,
W5500 automatically sends ARP-request to the peer’s IP address in order to acquire
MAC address information (used for communication of IP, UDP, or TCP). While waiting
for ARP-response from the peer, if there is no response during the configured RTR time,
a temporary timeout is occurred and ARP-request is retransmitted. It is repeated as
many as ‘RCR + 1’ times. Even after the ARP-request retransmissions are repeated as
‘RCR+1’ and there is no response to the ARP-request, the final timeout is occurred and
Sn_IR(TIMEOUT) becomes ‘1’. The time of final timeout (ARPTO) of ARP-request is as
below.
𝐴𝑅𝑃𝑇𝑂 = (𝑅𝑇𝑅 × 0.1𝑚𝑠) × (𝑅𝐶𝑅 + 1)
At the TCP packet retransmission timeout, W5500 transmits TCP packets (SYN, FIN,
RST, DATA packets) and waits for the acknowledgement (ACK) during the configured
RTR time and RCR. If there is no ACK from the peer, a temporary timeout occurs and
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W5500 Datasheet Version1.0.9
the TCP packet is retransmitted. The retransmission is repeated as many as ‘RCR+1’.
Even after TCP retransmission is repeated as ‘RCR+1’ and there is no response to the
TCP retransmission, the final timeout is occurred and Sn_IR(TIMEOUT) becomes ‘1’.
The time of final timeout (TCPTO) of TCP retransmission is as below.
𝑀
𝑇𝐶𝑃𝑇𝑂 = (∑(𝑅𝑇𝑅 × 2𝑁 )
+
((𝑅𝐶𝑅 − 𝑀) × 𝑅𝑇𝑅𝑀𝐴𝑋 )) × 0.1𝑚𝑠
𝑁=0
N : Retransmission count, 0≤N ≤ M
M : Minimum value when RTR x 2(M+1) > 65535 and 0 ≤ M ≤ RCR
RTRMAX : RTR x 2M
Ex) When RTR = 2000(0x07D0), RCR = 8(0x0008),
ARPTO = 2000 X 0.1ms X 9 = 1800ms = 1.8s
TCPTO = (0x07D0+0x0FA0+0x1F40+0x3E80+0x7D00+0xFA00+0xFA00+0xFA00+0xFA00) X 0.1ms
= (2000 + 4000 + 8000 + 16000 + 32000 + ((8 - 4) X 64000)) X 0.1ms
= 318000 X 0.1ms = 31.8s
PTIMER (PPP Link Control Protocol Request Timer Register) [R/W] [0x001C] [0x0028]
PTIMER configures the time for sending LCP echo request. The unit of time is 25ms.
Ex) in case that PTIMER is 200,
200 * 25(ms) = 5000(ms) = 5 seconds
PMAGIC (PPP Link Control Protocol Magic number Register) [R/W] [0x001D] [0x00]
PMAGIC configures the 4bytes magic number to be used in LCP echo request.
Ex) PMAGIC = 0x01
0x001D
0x01
LCP Magic number = 0x01010101
W5500 Datasheet Version1.0.9
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PHAR (Destination Hardware Address Register in PPPoE mode)
[R/W] [0x001E-0x0023] [0x0000]
PHAR should be written to the PPPoE server hardware address acquired in PPPoE
connection process
Ex) In case that destination hardware address is 00:08:DC:12:34:56
0x001E
0x001F
0x0020
0x0021
0x0022
0x0023
0x00
0x08
0xDC
0x12
0x34
0x56
PSID (Session ID Register in PPPoE mode) [R/W] [0x0024-0x0025] [0x0000]
PSID should be written to the PPPoE sever session ID acquired in PPPoE connection
process.
Ex) In case that Session ID is 0x1234
0x0024
0025
18 (0x12)
52(0x34)
PMRU (Maximum Receive Unit in PPPoE mode) [R/W] [0x0026-0x0027] [0xFFFF]
PMRU configures the maximum receive unit of PPPoE.
Ex) in case that maximum receive unit in PPPoE is 0x1234
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0x0026
0027
18 (0x12)
52 (0x34)
W5500 Datasheet Version1.0.9
UIPR (Unreachable IP Address Register) [R] [0x0028-0x002B] [0x00000000]
UPORTR (Unreachable Port Register) [R] [0x002C-0x002D] [0x0000]
W5500 receives an ICMP packet(Destination port unreachable) when data is sent to
a port number which socket is not open and UNREACH bit of IR becomes ‘1’ and UIPR
& UPORTR indicates the destination IP address & port number respectively.
Ex) In case of “192.168.0.11”
0x0028
0x0029
0x002A
0x002B
192 (0xC0)
168 (0xA8)
0 (0x00)
11 (0x0E)
0x002C
002D
18 (0x12)
52(0x34)
Ex) In case of “0x1234”
W5500 Datasheet Version1.0.9
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PHYCFGR (W5500 PHY Configuration Register) [R/W] [0x002E] [0b10111XXX]
PHYCFGR configures PHY operation mode and resets PHY. In addition, PHYCFGR
indicates the status of PHY such as duplex, Speed, Link.
Bit
Symbol
Description
Reset [R/W]
7
RST
When this bit is ‘0’, internal PHY is reset.
After PHY reset, it should be set as ‘1’.
Configure PHY Operation Mode
1: Configure with OPMDC[2:0] in PHYCFGR
0: Configure with the H/W PINs(PMODE[2:0])
This bit configures PHY operation mode with OPMDC[2:0] bits or
6
OPMD
PMODE[2:0] PINs. When W5500 is reset by POR or RSTn PIN, PHY
operation mode is configured with PMODE[2:0] PINs by default.
After POR or RSTn reset, user can re-configure PHY operation
mode with OPMDC[2:0]. If user wants to re-configure with
OPMDC[2:0], it should reset PHY by setting the RST bit to ‘0’ after
the user configures this bit as ‘1’ and OPMDC[2:0] .
Operation Mode Configuration Bit[R/W]
These bits select the operation mode of PHY such as following table.
5~3
2
OPMDC
DPX
5
4
3
Description
0
0
0
10BT Half-duplex, Auto-negotiation disabled
0
0
1
10BT Full-duplex, Auto-negotiation disabled
0
1
0
100BT Half-duplex, Auto-negotiation disabled
0
1
1
100BT Full-duplex, Auto-negotiation disabled
1
0
0
100BT Half-duplex, Auto-negotiation enabled
1
0
1
Not used
1
1
0
Power Down mode
1
1
1
All capable, Auto-negotiation enabled
Duplex Status [Read Only]
1: Full duplex
0: Half duplex
1
SPD
Speed Status [Read Only]
1: 100Mpbs based
0: 10Mpbs based
0
LNK
Link Status [Read Only]
1: Link up
0: Link down
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W5500 Datasheet Version1.0.9
VERSIONR (W5500 Chip Version Register) [R] [0x0039] [0x04]
VERSIONR always indicates the W5500 version as 0x04.
W5500 Datasheet Version1.0.9
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4.2
Socket Registers
Sn4_MR (Socket n Mode Register) [R/W] [0x0000] [0x00]
Sn_MR configures the option or protocol type of Socket n.
7
MULTI/
MFEN
Bit
6
BCASTB
5
4
ND / MC
UCASTB
/MMB
MIP6B
3
2
1
0
P3
P2
P1
P0
Symbol
Description
Multicasting in UDP mode
0 : disable Multicasting
1 : enable Multicasting
This bit is applied only during UDP mode(P[3:0] = ‘0010’).
To use multicasting, Sn_DIPR & Sn_DPORT should be respectively configured
with the multicast group IP address & port number before Socket n is
opened by OPEN command of Sn_CR
7
MULTI/
MFEN
MAC Filter Enable in MACRAW mode
0 : disable MAC Filtering
1 : enable MAC Filtering
This bit is applied only during MACRAW mode(P[3:0] = ‘0100’).
When set as ‘1’, W5500 can only receive broadcasting packet or packet
sent to itself. When this bit is ‘0’, W5500 can receive all packets on
Ethernet. If user wants to implement Hybrid TCP/IP stack, it is
recommended that this bit is set as ‘1’ for reducing host overhead to
process the all received packets.
Broadcast Blocking in MACRAW and UDP mode
0 : disable Broadcast Blocking
6
BCASTB
1 : enable Broadcast Blocking
This bit blocks to receive broadcasting packet during UDP mode(P[3:0] =
‘0010’). In addition, This bit does when MACRAW mode(P[3:0] = ‘0100’)
Use No Delayed ACK
5
ND/MC/
0 : Disable No Delayed ACK option
MMB
1 : Enable No Delayed ACK option
This bit is applied only during TCP mode (P[3:0] = ‘0001’).
4n
is Socket number (0, 1, 2, 3, 4, 5, 6, 7). n is set ‘SNUM[2:0]’ in Control Bits sets.
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W5500 Datasheet Version1.0.9
When this bit is ‘1’, It sends the ACK packet without delay as soon as a
Data packet is received from a peer. When this bit is ‘0’, It sends the ACK
packet after waiting for the timeout time configured by RTR.
Multicast
0 : using IGMP version 2
1 : using IGMP version 1
This bit is applied only during UDP mode(P[3:0] = ‘0010’) and MULTI = ‘1’.
It configures the version for IGMP messages (Join/Leave/Report).
Multicast Blocking in MACRAW mode
0 : disable Multicast Blocking
1 : enable Multicast Blocking
This bit is applied only when MACRAW mode(P[3:0] = ‘0100’). It blocks to
receive the packet with multicast MAC address.
UNICAST Blocking in UDP mode
0 : disable Unicast Blocking
1 : enable Unicast Blocking
This bit blocks receiving the unicast packet during UDP mode(P[3:0] =
4
UCASTB
MIP6B
‘0010’) and MULTI = ‘1’.
IPv6 packet Blocking in MACRAW mode
0 : disable IPv6 Blocking
1 : enable IPv6 Blocking
This bit is applied only during MACRAW mode (P[3:0] = ‘0100’).
It blocks to receiving the IPv6 packet.
3
P3
2
P2
1
0
Protocol
This configures the protocol mode of Socket n.
P1
P0
P3
P2
P1
P0
Meaning
0
0
0
0
Closed
0
0
0
1
TCP
0
0
1
0
UDP
0
1
0
0
MACRAW
* MACRAW mode should be only used in Socket 0.
W5500 Datasheet Version1.0.9
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Sn_CR (Socket n Command Register) [R/W] [0x0001] [0x00]
This is used to set the command for Socket n such as OPEN, CLOSE, CONNECT, LISTEN,
SEND, and RECEIVE. After W5500 accepts the command, the Sn_CR register is
automatically cleared to 0x00. Even though Sn_CR is cleared to 0x00, the command is
still being processed. To check whether the command is completed or not, please
check the Sn_IR or Sn_SR.
Value
Symbol
Description
Socket n is initialized and opened according to the protocol selected
in Sn_MR (P3:P0). The table below shows the value of Sn_SR
corresponding to Sn_MR.
Sn_MR (P[3:0])
0x01
OPEN
Sn_SR
Sn_MR_CLOSE (‘0000’)
-
Sn_MR_TCP (‘0001’)
SOCK_INIT (0x13)
Sn_MR_UDP (‘0010’)
SOCK_UDP (0x22)
S0_MR_MACRAW (‘0100’)
SOCK_MACRAW (0x42)
.
This is valid only in TCP mode (Sn_MR(P3:P0) = Sn_MR_TCP). In this
mode, Socket n operates as a ‘TCP server’ and waits for
connection-
request (SYN packet) from any ‘TCP client’.
The Sn_SR changes the state from SOCK_INIT to SOCKET_LISTEN.
0x02
LISTEN
When a ‘TCP client’ connection request is successfully established,
the Sn_SR changes from SOCK_LISTEN to SOCK_ESTABLISHED and the
Sn_IR(0) becomes ‘1’. But when a ‘TCP client’ connection request is
failed, Sn_IR(3) becomes ‘1’ and the status of Sn_SR changes to
SOCK_CLOSED.
This is valid only in TCP mode and operates when Socket n acts as
‘TCP client’. To connect, a connect-request (SYN packet) is sent to
‘TCP server’ configured by Sn_DIPR & Sn_DPORT(destination address
& port). If the connect-request is successful, the Sn_SR is changed to
SOCK_ESTABLISHED and the Sn_IR(0) becomes ‘1’.
0x04
CONNECT
The connect-request fails in the following three cases.
1. When a ARPTO occurs (Sn_IR(3)=‘1’) because the destination
hardware address is not acquired through the ARP-process.
2. When a SYN/ACK packet is not received and TCPTO (Sn_IR(3) =
‘1 )
3. When a RST packet is received instead of a SYN/ACK packet.
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W5500 Datasheet Version1.0.9
In these cases, Sn_SR is changed to SOCK_CLOSED.
Valid only in TCP mode.
Regardless of ‘TCP server’ or ‘TCP client’, the DISCON command
processes the disconnect-process (‘Active close’ or ‘Passive close’).
Active close: it transmits disconnect-request(FIN packet) to the
connected peer
Passive close: When FIN packet is received from peer,
a FIN packet is replied back to the peer.
0x08
DISCON
When the disconnect-process is successful (that is, FIN/ACK packet is
received
successfully),
Sn_SR
is
changed
to
SOCK_CLOSED.
Otherwise, TCPTO occurs (Sn_IR(3)=‘1)= and then Sn_SR is changed to
SOCK_CLOSED.
cf> If CLOSE is used instead of DISCON, only Sn_SR is changed to
SOCK_CLOSED without disconnect-process.
If a RST packet is received from a peer during communication, Sn_SR
is unconditionally changed to SOCK_CLOSED.
0x10
CLOSE
Close Socket n.
Sn_SR is changed to SOCK_CLOSED.
SEND transmits all the data in the Socket n TX buffer. For more
0x20
SEND
details, please refer to Socket n TX Free Size Register (Sn_TX_FSR),
Socket n, TX Write Pointer Register(Sn_TX_WR), and Socket n TX Read
Pointer Register(Sn_TX_RD).
Valid only in UDP mode.
The basic operation is same as SEND. Normally SEND transmits data
after destination hardware address is acquired by the automatic ARP-
0x21
SEND_MAC
process(Address Resolution Protocol). But SEND_MAC transmits data
without the automatic ARP-process. In this case, the destination
hardware address is acquired from Sn_DHAR configured by host,
instead of APR-process.
Valid only in TCP mode.
It checks the connection status by sending 1byte keep-alive packet.
If the peer cannot respond to the keep-alive packet during timeout
0x22
SEND_KEEP
W5500 Datasheet Version1.0.9
time, the connection is terminated and the timeout interrupt will
occur.
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RECV completes the processing of the received data in Socket n RX
Buffer by using a RX read pointer register (Sn_RX_RD).
0x40
RECV
For more details, refer to Socket n RX Received Size Register
(Sn_RX_RSR), Socket n RX Write Pointer Register (Sn_RX_WR), and
Socket n RX Read Pointer Register (Sn_RX_RD).
Sn_IR (Socket n Interrupt Register) [RCW1] [0x0002] [0x00]
Sn_IR indicates the status of Socket Interrupt such as establishment, termination,
receiving data, timeout). When an interrupt occurs and the corresponding bit of
Sn_IMR is ‘1’, the corresponding bit of Sn_IR becomes ‘1’.
In order to clear the Sn_IR bit, the host should write the bit to ‘1’.
7
6
Reserved
5
Reserved
Bit
Symbol
7~5
Reserved
4
SEND_OK
3
TIMEOUT
2
RECV
1
DISCON
Reserved
4
SEND_OK
3
TIMEOUT
2
RECV
1
DISCON
0
CON
Description
Reserved
Sn_IR(SENDOK) Interrupt
This is issued when SEND command is completed.
Sn_IR(TIMEOUT) Interrupt
This is issued when ARPTO or TCPTO occurs.
Sn_IR(RECV) Interrupt
This is issued whenever data is received from a peer.
Sn_IR(DISCON) Interrupt
This is issued when FIN or FIN/ACK packet is received from a peer.
Sn_IR(CON) Interrupt
0
CON
This is issued one time when the connection with peer is successful
and then Sn_SR is changed to SOCK_ESTABLISHED.
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W5500 Datasheet Version1.0.9
Sn_SR (Socket n Status Register) [R] [0x0003] [0x00]
Sn_SR indicates the status of Socket n. The status of Socket n is changed by Sn_CR
or some special control packet as SYN, FIN packet in TCP.
Value
Symbol
0x00
SOCK_CLOSED
Description
This indicates that Socket n is released.
When DISCON, CLOSE command is ordered, or when a timeout
occurs, it is changed to SOCK_CLOSED regardless of previous
status.
0x13
SOCK_INIT
This indicates Socket n is opened with TCP mode.
It is changed to SOCK_INIT when Sn_MR (P[3:0]) = ‘0001’ and
OPEN command is ordered.
After SOCK_INIT, user can use LISTEN /CONNECT command.
0x14
SOCK_LISTEN
This indicates Socket n is operating as ‘TCP server’ mode and
waiting for connection-request (SYN packet) from a peer
(‘TCP client’).
It will change to SOCK_ESTALBLISHED when the connectionrequest is successfully accepted.
Otherwise it will change to SOCK_CLOSED after TCPTO
occurred (Sn_IR(TIMEOUT) = ‘1’).
0x17
SOCK_ESTABLISHED
This indicates the status of the connection of Socket n.
It changes to SOCK_ESTABLISHED when the ‘TCP SERVER’
processed the SYN packet from the ‘TCP CLIENT’ during
SOCK_LISTEN, or when the CONNECT command is successful.
During SOCK_ESTABLISHED, DATA packet can be transferred
using SEND or RECV command.
0x1C
SOCK_CLOSE_WAIT
This indicates Socket n received the disconnect-request (FIN
packet) from the connected peer. This is half-closing status,
and data can be transferred. For full-closing, DISCON
command is used. But For just-closing, CLOSE command is
used.
0x22
SOCK_UDP
This indicates Socket n is opened in UDP mode(Sn_MR(P[3:0])
= ‘0010’).
It changes to SOCK_UDP when Sn_MR(P[3:0]) = ‘0010’) and
OPEN command is ordered.
Unlike TCP mode, data can be transfered without the
connection-process.
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49 / 66
0x42
SOCK_MACRAW
This indicates Socket 0 is opened in MACRAW mode
(S0_MR(P[3:0]) = ‘0100’)and is valid only in Socket 0.
It changes to SOCK_MACRAW when S0_MR(P[3:0] = ‘0100’ and
OPEN command is ordered.
Like UDP mode socket, MACRAW mode Socket 0 can transfer
a MAC packet (Ethernet frame) without the connectionprocess.
The following table shows a temporary status indicated during changing the status
of Socket n.
Value
Symbol
Description
0x15
SOCK_SYNSENT
This indicates Socket n sent the connect-request packet
(SYN packet) to a peer.
It is temporarily shown when Sn_SR is changed from
SOCK_INIT to SOCK_ESTABLISHED by CONNECT command.
If connect-accept(SYN/ACK packet) is received from the
peer at SOCK_SYNSENT, it changes to SOCK_ESTABLISHED.
Otherwise, it changes to SOCK_CLOSED after TCPTO
(Sn_IR[TIMEOUT] = ‘1’) is occurred.
0x16
SOCK_SYNRECV
It indicates Socket n successfully received the connectrequest packet (SYN packet) from a peer.
If socket n sends the response (SYN/ACK
peer successfully,
packet) to the
it changes to SOCK_ESTABLISHED. If
not, it changes to SOCK_CLOSED after timeout occurs
(Sn_IR[TIMEOUT] = ‘1’).
0x18
SOCK_FIN_WAIT
0x1A
SOCK_CLOSING
0X1B
SOCK_TIME_WAIT
These indicate Socket n is closing.
These are shown in disconnect-process such as active-close
and passive-close.
When Disconnect-process is successfully completed, or
when timeout occurs, these change to SOCK_CLOSED.
0X1D
SOCK_LAST_ACK
This indicates Socket n is waiting for the response (FIN/ACK
packet) to the disconnect-request (FIN packet) by passiveclose.
It changes to SOCK_CLOSED when Socket n received the
response
successfully,
or
when
timeout
occurs
(Sn_IR[TIMEOUT] = ‘1’).
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W5500 Datasheet Version1.0.9
Sn_PORT (Socket n Source Port Register) [R/W] [0x0004-0x0005] [0x0000]
Sn_PORT configures the source port number of Socket n. It is valid when Socket n is
used in TCP/UDP mode. It should be set before OPEN command is ordered.
Ex) In case of Socket 0 Port = 5000(0x1388), configure as below,
0x0004
0x0005
0x13
0x88
Sn_DHAR (Socket n Destination Hardware Address Register)
[R/W] [0x0006-0x000B] [0xFFFFFFFFFFFF]
Sn_DHAR configures the destination hardware address of Socket n when using
SEND_MAC command in UDP mode or it indicates that it is acquired in ARP-process by
CONNECT/SEND command.
Ex) In case of Socket 0 Destination Hardware address = 08.DC.00.01.02.10, configure as below.
0x0006
0x0007
0x0008
0x0009
0x000A
0x000B
0x08
0xDC
0x00
0x01
0x02
0x0A
Sn_DIPR (Socket n Destination IP Address Register)
[R/W] [0x000C-0x000F] [0x00000000]
Sn_DIPR configures or indicates the destination IP address of Socket n. It is valid
when Socket n is used in TCP/UDP mode.
In TCP client mode, it configures an IP address of ‘TCP server’ before CONNECT
command.
In TCP server mode, it indicates an IP address of ‘TCP client’ after successfully
establishing connection.
In UDP mode, it configures an IP address of peer to be received the UDP packet by
SEND or SEND_MAC command.
Ex) In case of Socket 0 Destination IP address = 192.168.0.11, configure as below.
0x000C
0x000D
0x000E
0x000F
192 (0xC0)
168 (0xA8)
0 (0x00)
11 (0x0B)
Sn_DPORT (Socket n Destination Port Register) [R/W] [0x0010-0x0011] [0x00]
Sn_DPORT configures or indicates the destination port number of Socket n. It is valid
when Socket n is used in TCP/UDP mode.
In TCP client mode, it configures the listen port number of ‘TCP server’ before
CONNECT command.
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In TCP server mode, it indicates the port number of ‘TCP client’ after successfully
establishing connection.
In UDP mode, it configures the port number of peer to be transmitted the UDP packet
by SEND/SEND_MAC command.
Ex) In case of Socket 0 Destination Port = 5000(0x1388), configure as below,
0x0010
0x0011
0x13
0x88
Sn_MSSR (Socket n Maximum Segment Size Register) [R/W] [0x0012-0x0013] [0x0000]
This register is used for MSS (Maximum Segment Size) of TCP, and the register displays MSS set
by the other party when TCP is activated in Passive Mode.
Ex) In case of Socket 0 MSS = 1460 (0x05B4), configure as below,
0x0012
0x0013
0x05
0xB4
Sn_TOS (Socket n IP Type of Service Register) [R/W] [0x0015] [0x00]
Sn_TOS configures the TOS(Type Of Service field in IP Header) of Socket n.
It is set before OPEN command.
For more the details, refer to http://www.iana.org/assignments/ip-parameters.
Sn_TTL (Socket n TTL Register) [R/W] [0x0016] [0x80]
Sn_TTL configures the TTL(Time To Live field in IP header) of Socket n.
It is set before OPEN command.
For more the details, refer to http://www.iana.org/assignments/ip-parameters.
Sn_RXBUF_SIZE (Socket n RX Buffer Size Register) [R/W] [0x001E] [0x02]
Sn_RXBUF_SIZE configures the RX buffer block size of Socket n. Socket n RX Buffer
Block size can be configured with 1,2,4,8, and 16 Kbytes. If a different size is
configured, the data cannot be normally received from a peer.
Although Socket n RX Buffer Block size is initially configured to 2Kbytes, user can reconfigure its size using Sn_RXBUF_SIZE. The total sum of Sn_RXBUF_SIZE cannot be
exceed 16Kbytes. When exceeded, the data reception error is occurred.
When all Sn_RXBUF_SIZE have been configured, Socket n RX Buffer is allocated with
the configured size in 16KB RX Memory and is assigned sequentially from Socket 0 to
Socket 7.
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W5500 Datasheet Version1.0.9
Socket n RX Buffer Block can be accessible with the 16bits Offset Address ranged from
0x0000 to 0xFFFF regardless of the configured size. (Refer to Sn_RX_RD & Sn_RX_WR).
Value (dec)
0
1
2
4
8
16
Buffer size
0KB
1KB
2KB
4KB
8KB
16KB
Ex) Socket 0 RX Buffer Size = 8KB
0x001E
0x08
Sn_TXBUF_SIZE (Socket n TX Buffer Size Register) [R/W] [0x001F] [0x02]
Sn_TXBUF_SIZE configures the TX buffer block size of Socket n. Socket n TX
Buffer Block size can be configured with 1,2,4,8, and 16 Kbytes. If a different size
is configured, the data can’t be normally transmitted to a peer.
Although Socket n TX Buffer Block size is initially configured to 2Kbytes, user can
be re-configure its size using Sn_TXBUF_SIZE. The total sum of Sn_TXBUF_SIZE
cannot be exceed 16Kbytes. When exceeded, the data transmission error is
occurred.
When all Sn_TXBUF_SIZE have been configured, Socket n TX Buffer is allocated
with the configured size in 16KB TX Memory and is assigned sequentially from
Socket 0 to Socket 7.
Socket n TX Buffer Block can be accessible with 16bits Offset Address ranged
from 0x0000 to 0xFFFF regardless of the configured size. (Refer to Sn_TX_WR &
Sn_TX_RD).
Value (dec)
0
1
2
4
8
16
Buffer size
0KB
1KB
2KB
4KB
8KB
16KB
Ex) Socket 0 TX Buffer Size = 4KB
0x001F
0x04
Sn_TX_FSR (Socket n TX Free Size Register) [R] [0x0020-0x0021] [0x0800]
Sn_TX_FSR indicates the free size of Socket n TX Buffer Block. It is initialized to the
configured size by Sn_TXBUF_SIZE. Data bigger than Sn_TX_FSR should not be saved
in the Socket n TX Buffer because the bigger data overwrites the previous saved data
not yet sent. Therefore, check before saving the data to the Socket n TX Buffer, and
if data is equal or smaller than its checked size, transmit the data with
W5500 Datasheet Version1.0.9
53 / 66
SEND/SEND_MAC command after saving the data in Socket n TX buffer. But, if data is
bigger than its checked size, transmit the data after dividing into the checked size
and saving in the Socket n TX buffer.
If Sn_MR(P[3:0]) is not TCP mode(‘0001’), it is automatically calculated as the
difference between ‘Socket n TX Write Pointer (Sn_TX_WR)’ and ‘Socket n TX Read
Pointer (Sn_TX_RD)’.
If Sn_MR(P[3:0]) is TCP mode(‘0001’), it is automatically calculated
as the
difference between Sn_TX_WR and the internal ACK pointer which indicates the point
of data is received already by the connected peer.
Ex) In case of 2048(0x0800) in S0_TX_FSR,
0x0020
0x0021
0x08
0x00
Note) Because this register for representing the size information is 16 bits, it is
impossible to read all bytes at the same time. Before 16 bit-read operation is not
completed, the value may be changed.
Therefore, it is recommended that you read all 16-bits twice or more until getting
the same value.
Sn_TX_RD (Socket n TX Read Pointer Register) [R] [0x0022-0x0023] [0x0000]
Sn_TX_RD is initialized by OPEN command. However, if Sn_MR(P[3:0]) is TCP
mode(‘0001’), it is re-initialized while connecting with TCP.
After its initialization, it is auto-increased by SEND command. SEND command
transmits the saved data from the current Sn_TX_RD to the Sn_TX_WR in the Socket n
TX Buffer. After transmitting the saved data, the SEND command increases the
Sn_TX_RD as same as the Sn_TX_WR.
If its increment value exceeds the maximum value 0xFFFF, (greater than 0x10000
and the carry bit occurs), then the carry bit is ignored and will automatically update
with the lower 16bits value.
Sn_TX_WR (Socket n TX Write Pointer Register) [R/W] [0x0024-0x0025] [0x0000]
Sn_TX_WR is initialized by OPEN command. However, if Sn_MR(P[3:0]) is TCP
mode(‘0001’), it is re-initialized while connecting with TCP.
It should be read or to be updated like as follows.
1.
Read the starting address for saving the transmitting data.
2.
Save the transmitting data from the starting address of Socket n TX
buffer.
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W5500 Datasheet Version1.0.9
3.
After saving the transmitting data, update Sn_TX_WR to the
increased value as many as transmitting data size. If the increment value
exceeds the maximum value 0xFFFF(greater than 0x10000 and the carry
bit occurs), then the carry bit is ignored and will automatically update
with the lower 16bits value.
4.
Transmit the saved data in Socket n TX Buffer by using SEND/SEND
command
Sn_RX_RSR (Socket n Received Size Register) [R] [0x0026-0x0027] [0x0000]
Sn_RX_RSR indicates the data size received and saved in Socket n RX Buffer. Sn_RX_RSR
does not exceed the Sn_RXBUF_SIZE and is calculated as the difference between
‘Socket n RX Write Pointer (Sn_RX_WR)’ and ‘Socket n RX Read Pointer (Sn_RX_RD)’.
Ex) In case of 2048(0x0800) in S0_RX_RSR,
0x0026
0x0027
0x08
0x00
Note) Because this register for representing the size information is 16 bits, it is
impossible to read all bytes at the same time. Before 16 bit-read operation is not
completed, the value may be changed.
Therefore, it is recommended that you read all 16-bits twice or more until getting
the same value.
Sn_RX_RD (Socket n RX Read Data Pointer Register) [R/W] [0x0028-0x0029] [0x0000]
Sn_RX_RD is initialized by OPEN command. Make sure to be read or updated as
follows.
1. Read the starting save address of the received data
2. Read data from the starting address of Socket n RX Buffer.
3. After reading the received data, Update Sn_RX_RD to the increased value as many
as the reading size. If the increment value exceeds the maximum value 0xFFFF,
that is, is greater than 0x10000 and the carry bit occurs, update with the lower
16bits value ignored the carry bit.
4. Order RECV command is for notifying the updated Sn_RX_RD to W5500.
Ex) In case of 2048(0x0800) in S0_RX_RD,
0x0028
0x0029
0x08
0x00
Sn_RX_WR (Socket n RX Write Pointer Register) [R] [0x002A-0x002B] [0x0000]
W5500 Datasheet Version1.0.9
55 / 66
Sn_RX_WR is initialized by OPEN command and it is auto-increased by the data
reception.
If the increased value exceeds the maximum value 0xFFFF, (greater than 0x10000
and the carry bit occurs), then the carry bit is ignored and will automatically update
with the lower 16bits value.
Ex) In case of 2048(0x0800) in S0_RX_WR,
0x002A
0x002B
0x08
0x00
Sn_IMR (Socket n Interrupt Mask Register) [R/W] [0x002C] [0xFF]
Sn_IMR masks the interrupt of Socket n.
Each bit corresponds to each bit of Sn_IR.
When a Socket n Interrupt is occurred and the corresponding bit of Sn_IMR is ‘1’, the
corresponding bit of Sn_IR becomes ‘1’.
When both the corresponding bit of Sn_IMR and Sn_IR are ‘1’ and the n-th bit of SIR
is ‘1’, Host is interrupted by asserted INTn PIN to low.
7
6
Reserved
Reserved
5
4
Reserved
SEND_OK
3
2
TIMEOUT
Bit
Symbol
7~5
Reserved
4
SENDOK
Sn_IR(SENDOK) Interrupt Mask
3
TIMEOUT
Sn_IR(TIMEOUT) Interrupt Mask
2
RECV
1
DISCON
0
CON
1
RECV
DISCON
0
CON
Description
Reserved
Sn_IR(RECV) Interrupt Mask
Sn_IR(DISCON) Interrupt Mask
Sn_IR(CON) Interrupt Mask
Sn_FRAG (Socket n Fragment Register) [R/W] [0x002D-0x002E] [0x4000]
Sn_FRAG configures the FRAG(Fragment field in IP header).
Ex) Sn_FRAG0 = 0x0000 (Don’t Fragment)
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0x002D
0x002E
0x00
0x00
W5500 Datasheet Version1.0.9
Sn_KPALVTR (Socket n Keep Alive Time Register) [R/W] [0x002F] [0x00]
Sn_KPALVTR configures the transmitting timer of ‘KEEP ALIVE(KA)’ packet of
SOCKETn. It is valid only in TCP mode, and ignored in other modes. The time unit is
5s.
KA packet is transmittable after Sn_SR is changed to SOCK_ESTABLISHED and after
the data is transmitted or received to/from a peer at least once.
In case of 'Sn_KPALVTR > 0', W5500 automatically transmits KA packet after timeperiod for checking the TCP connection (Auto-keepalive-process).
In case of 'Sn_KPALVTR = 0', Auto-keep-alive-process will not operate, and KA packet
can be transmitted by SEND_KEEP command by the host (Manual-keep-alive-process).
Manual-keep-alive-process is ignored in case of 'Sn_KPALVTR > 0'.
Ex) Sn_KPALVTR = 10 (Keep Alive packet will be transmitted every 50 seconds.)
0x002F
0x0A
W5500 Datasheet Version1.0.9
57 / 66
Electrical Specifications
5.1
Absolute Maximum Ratings
Symbol
Parameter
Rating
Unit
VDD
DC Supply voltage
-0.5 to 4.6
V
VIN
DC input voltage
-0.5 to 6
V
DC output voltage
-0.5 to 4.6
V
IIN
DC input current
5
mA
TOP
Operating temperature
-40 to +85
C
TJMAX
Maximum junction temperature
125
C
TSTG
Storage temperature
-65 to +150
C
VOUT
*COMMENT: Stressing the device beyond the ‘Absolute Maximum Ratings’ may cause
permanent damage.
5.2
Absolute Maximum Ratings (Electrical Sensitivity)
Electrostatic discharge (ESD)
Symbol
VESD(HBM)
VESD(MM)
VESD(CDM)
Parameter
Test Condition
Electrostatic discharge
TA = +25 °C
voltage (human body
conforming to MIL-STD
model)
883F Method 3015.7
Electrostatic discharge
TA = +25 °C
voltage (man machine
conforming to JEDEC
model)
EIA/JESD22 A115-A
Electrostatic discharge
TA = +25 °C
voltage (charge device
conforming to JEDEC
model)
JESD22 C101-C
Class
Maximum
value(1)
Unit
2
2000
V
B
200
V
III
500
V
Static latchup
Symbol
LU
Parameter
Static latch-up class
Test Condition
Class
TA = +25 °C conforming
I
Maximum
value(1)
≥ ±200
Unit
mA
to JESD78A
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W5500 Datasheet Version1.0.9
5.3
DC Characteristics
(Test Condition: Ta = –40 to 85°C)
Symbol
Parameter
VDD
Supply voltage
VIH
High level input
Test Condition
Apply VDD, AVDD
Min
Typ
Max
Unit
2.97
3.3
3.63
V
2.0
5.5
V
- 0.3
0.8
V
voltage
VIL
Low level input
voltage
VT
Threshold point
All inputs except XI
1.30
1.41
1.53
V
VT+
Schmitt trig Low to
All inputs except XI
1.53
1.64
1.73
V
All inputs except XI
0.95
1.02
1.09
V
-40
25
125
°C
1
A
High Threshold
point
VT-
Schmitt trig High to
Low Threshold point
TJ
Junction
temperature
IL
Input Leakage
Current
RPU
Pull-up Resistor
SCSn, RSTn, PMODE[2:0]
62
77
112
Kohm
RPD
Pull-down Resistor
RSVD(Pin 23, Pin 38 ~
48
85
174
Kohm
0.4
V
Pin 42)
VOL
VOH
IOL
IOH
IDD1
Low level output
IOL = 8mA,
voltage
All outputs except XO
High level output
IOH = 8mA,
voltage
All outputs except XO
Low level output
VOL = 0.4V, All outputs
Current
except XO
High level output
VOH = 2.4V, All outputs
Current
except XO
Supply Current
VDD=3.3V, AVDD=3.3V,
(Normal operation
Ta = 25°C
2.4
V
8.6
13.9
18.9
mA
12.5
26.9
47.1
mA
132
mA
13
mA
mode)
IDD2
Supply Current
PHY Power Down mode,
(Power Down mode)
VDD=3.3V, AVDD=3.3V,
Ta = 25°C
W5500 Datasheet Version1.0.9
59 / 66
5.4
Power Dissipation
(Test Condition: VDD=3.3V, AVDD=3.3V, Ta = 25°C)
Condition
Min
Typ
Max
Unit
100M Link
-
128
-
mA
10M Link
-
75
-
mA
Un-Link (Auto-negotiation mode)
-
65
-
mA
100M Transmitting
-
132
-
mA
10M Transmitting
-
79
-
mA
Power Down mode
-
13
-
mA
5.5
AC Characteristics
5.5.1
Reset Timing
TRC
RSTn
TPL
PLOCK
(Internal)
Figure 22. Reset Timing
Symbol
5.5.2
Description
TRC
Reset Cycle Time
TPL
RSTn to internal PLOCK (PLL Lock)
Min
Max
500 us
-
-
1 ms
Wake up Time
Voltage Regulator Wake up Time: 10us
5.5.3
Crystal Characteristics
Parameter
Range
Frequency
25 MHz
Frequency Tolerance (at 25℃)
±30 ppm
Shunt Capacitance
7pF Max
Drive Level
59.12uW
Load Capacitance
18pF
Aging (at 25℃)
±3ppm / year Max
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W5500 Datasheet Version1.0.9
5.5.4
SPI Timing
TCS
SCSn
VIH
VIL
TCSS
SCLK
TCSH
VIH
TWH
VIL
TDS
MOSI
TWL
TDH
VIH
VIL
TOV
MISO
VOH
VOL
TOH
TCHZ
HI-Z
HI-Z
Figure 23. SPI Timing
Symbol
Min
Max
80/33.3
Units
5
FSCK
SCK Clock Frequency
TWH
SCK High Time
6
ns
TWL
SCK Low Time
6
ns
TCS
SCSn High Time
30
ns
TCSS
SCSn Setup Time
5
TCSH
SCSn Hold Time
5
ns
TDS
Data In Setup Time
3
ns
TDH
Data In Hold Time
3
ns
TOV
Output Valid Time
TOH
Output Hold Time
TCHZ
5
Description
-
ns
5
ns
0
SCSn High to Output Hi-Z
MHz
ns
2.1
6
ns
Theoretical Guaranteed Speed
Even though theoretical design speed is 80MHz, the signal in the high speed may be distorted because
of the circuit crosstalk and the length of the signal line. The minimum guaranteed speed of the SCLK
is 33.3 MHz which was tested and measured with the stable waveform.
Please refer to the SPI Application Note which shows the WIZnet test environment and results.
6
2.1ns is when pn loaded with 30pF. The time is shorter with lower capacitance.
W5500 Datasheet Version1.0.9
61 / 66
5.5.5
Transformer Characteristics
Parameter
Transmit End
Receive End
Turn Ratio
1:1
1:1
Inductance
350 uH
350 uH
Figure 24. Transformer Type
5.5.6
MDIX
W5500 does not support auto-MDIX feature.
Thus, user should use straight-through cables to connect to other switches or routers and
crossover cables to connect to devices such as servers, workstations or another W5500.
However, user can use either type of cable to connect to other devices with auto-MDIX
enabled, and the interface automatically corrects for any incorrect cabling.
62 / 66
W5500 Datasheet Version1.0.9
IR Reflow Temperature Profile (Lead-Free)
Moisture Sensitivity Level : 3
Dry Pack Required: Yes
Average Ramp-Up Rate
3° C/second max.
(Tsmax to Tp)
Preheat
– Temperature Min (Tsmin)
150 °C
– Temperature Max (Tsmax)
200 °C
– Time (tsmin to tsmax)
60-120 seconds
Time maintained above:
– Temperature (TL)
217 °C
– Time (tL)
60-150 seconds
Peak/Classification Temperature (Tp)
265 + 0/-5°C
Time within 5 °C of actual Peak Temperature (tp)
30 seconds
Ramp-Down Rate
6 °C/second max.
Time 25 °C to Peak Temperature
8 minutes max.
Figure 25. IR Reflow Temperature
W5500 Datasheet Version1.0.9
63 / 66
Package Descriptions
Note
1. These dimensions do not include mold
protrusion.
2. (
) is reference.
3. [
] is ass’y out quality.
4. UNIT: mm
Figure 26. Package Dimensions
64 / 66
W5500 Datasheet Version1.0.9
Document History Information
Version
Date
Ver. 1.0.0
1AUG2013
Descriptions
Initial Release
Corrected duplicated statements and typing errors (P.14, 23, 24, 28,
Ver. 1.0.1
13SEP2013
39, 51)
Corrected descriptions (P.35)
1.
Ver. 1.0.2
14NOV2013
Changed “descriptions of pin
at 1.1 Pin Descriptions”(P.10)
from It must be tied to GND to NC(PIN38~42)
2. Corrected typing error :
from 0x02 to 0x42 value of SOCK_MACRAW at 4.2 Socket Registers(P.50)
Ver. 1.0.3
29MAY2014
Ver. 1.0.4
13JUN2014
1. Corrected “Sn_MSSR
at 4.2 Socket Register”(P.53)
wrong descriptions of Sn_MSSR about FMTU/MTU
1. Added Note about reading size register value (P.56, 58)
2. Added IR Reflow Temperature Profile (P.66)
1. Added description for MISO pin (P.11)
The SCSn signal defines MISO pin output value.
2. Modified the register notation (P.33), Modified the register
Ver. 1.0.5
10NOV2014
notation “Sn_IR at 4.2 Socket Register” (P.49)
from [R] to [RCW1]
3. Corrected typing error:
from DICON to DISCON of Sn_SR at 4.2 Socket Register (P.50)
1. Corrected typing error :
Ver. 1.0.6
30DEC2014
from 0x02 to 0x42 value of SOCK_MACRAW “Sn_CR at 4.2 Socket
Registers”(P.47)
Ver. 1.0.7
24FEB2016
Ver. 1.0.8
19MAY2017
Ver. 1.0.9
22MAY2019
W5500 Datasheet Version1.0.9
1. Corrected 𝐼𝐴𝑊𝑇 (Interrupt Assert Wait Time) (P.34)
3
2. Notice the information of 𝑃𝐿𝐿𝑐𝑙𝑘 (P.34)
1. Corrected Driver Level Range Unit uW/MHz to uW (5.5.3 Crystal
Characteristics) (P.60)
1. Corrected Sn_IMR Description (P.55)
2. Corrected Junction temperature Min value TJ (P.57)
65 / 66
3. Added Maximum junction temperature TJMAX (P.58)
Copyright Notice
Copyright 2013 WIZnet Co., Ltd. All Rights Reserved.
Technical Support: support@wiznet.co.kr
Sales & Distribution: sales@wiznet.co.kr
For more information, visit our website at http://www.wiznet.co.kr
66 / 66
W5500 Datasheet Version1.0.9