ETC RTL8801

RTL8801 Preliminary
RTL8801 PHY/IEEE 1394A
3 port 100/200/400 Mb/s Cable Transceiver/Arbiter Chip
1. Features
♦ Fully support provisions of IEEE1394-1995
for High- Performance Serial Bus and the
P1394a draft 2.0 standard
♦ Provides three fully compliant cables ports at
100/200/400 Mbits/s and available with one,
two or three ports
♦ Fully compliant with Open HCI requirements
♦ Full P1394a additional function support
♦ Support optional 1394 Annex J electrical
isolation barrier at PHY-link interface
♦ Support power-down feature to conserve
energy in battery powered applications
♦ Cable power presence monitoring
♦ Separate cable bias (TPBIAS) and driver
termination voltage supply for each port
♦ Encode and decode functions included for
data-strobe bit level encoding
♦ Support LPS/link-on pin for PHY-link
interface
♦ Incoming data resynchronized to local clock
♦ Single 24.576 MHZ crystal provide
transmit/receive data at 100/200/400 Mbits/s
and LLC clock at 49.152 M
♦ Node power-class information signaling for
system power management
♦ Adaptive equalizer
♦ Easy configured as a repeater
♦ Single 3.3V power supply
♦ 64 pin LQFP package
2. General Description
The RTL8801 provides three-port physical layer(PHY) function in a cable-based IEEE 1394-1995
and IEEE P1394a network. Each cable port incorporates two differential line transceivers. The
transceivers include circuitry to monitor the line conditions as needed for determining connection
status, for initialization and arbitration, and for packet reception and transmission.
Data bits to be transmitted through the cable ports are received from the Link on 2/4/8 data lines
(D0-D8), and are latched internally in the RTL8801 in synchronization with the 49.152 MHZ
system clock these bits are combined serially, encoded, and transmitted at 98.304 , 196.608 or
393.216Mbps as the outbound data-strobe information stream. During transmission, the encoded
data transmitted differential on the TPB cable pair(s), and the encoded strobe information is
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RTL8801 Preliminary
transmitted differentially on the TPA cable pair(s).
During packet reception the TPA and TPB transmitters of the receiving cable port are disabled, and
the receivers for that port are enabled. The encoded data information is received on the TPA cable
pair, and the encoded Strobe information is received on the TPB cable pair. The received
data-strobe information is decoded to recover the received clock signal and the serial data bits. The
serial data bits are split into two or four parallel transmitted (repeated) out of the other active
(connected) cable ports.
Both the TPA and TPB cable interfaces incorporate differential comparators to monitor the line
states during initialization and arbitration. The output of these comparators are used by the internal
logic to determine the arbitration status. The TPA channel monitors the incoming cable
common-mode voltage. The value of this common mode voltage is used during arbitration to set the
speed of the next packet transmission. In addition, the TPB channel monitors the incoming cable
common-mode voltage for the presence of the remotely supplied twisted-pair bias voltage. The
presence or absence of this common-mode voltage is used as an indication of cable connection
status. The cable connection status signal is internally debounced in the RTL8801 on a cable
disconnect-to-connect. The debounced cable connection status signal initiates a bus reset. On a
cable disconnect-to-connect a debounce delay is incorporated. There is no delay on a cable
disconnect.
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RTL8801 Preliminary
PGND
PLLVDD
BVDD
TGND
PLLGND
BTSET
BGND
ADVDD
PLLGND
LREQ
TPBIAS3
DVSS
CTL0
TPA3+
TPA3-
CTL1
D0
TPB3+
TPB3-
D1
DVDD
PVDD
TPBIAS2
D2
D3
TPA2+
TPA2-
RTL8801
D4
TPB2+
D5
TPB2-
D6
TPBIAS1
RGND
TVDD
RVDD
TPB1-
TEST1
AGND
LPS
DXVDD
TEST2
TPB1+
CPS
DXVSS
LACT
PC2
ISO\
TPA1-
PC0
PC1
TPA1+
LKON/C
PDISABLE
D7
DVSS
DVDD
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XI
ADGND
RESET\
XO
SCLK
DVDD
DVSS
3. Pin Assignment
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RTL8801 Preliminary
4. Pin Descriptions
Symbol
C/LKON
Type
I/O
CNA
O
CPS
I
LPS
I
LREQ
I
ISO\
I
CTL0
CTL1
D0-D7
SYSCLK
I/O
I/O
O
TPA1+
TPA1-
I/O
TPA2+
TPA2-
I/O
TPA3+
TPA3-
I/O
TPB1+
TPB1-
I/O
TPB2+
TPB2-
I/O
TPB3+
TPB3-
I/O
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Pin(s) No.
18
Description
(input) Bus manager capable. When set as input, C/LKON specifies in
the Self-ID packet that the node is bus manager capable.
(output) Link on. When set as an output, C/LKON indicates the
reception of a link-on packet by asserting a 6.114 MHZ square wave
signal.
15
CNA is asserted high when none of the PHY ports are connected to
another active port. This circuit remains active during the power down
mode.
24
Cable power status. CPS is normally connected to the cable power
through a 400-Kohm resistor. This circuit drivers an internal
comparator that detects the presence of cable power.
16
Link power status. LPS is connected to either the VDD supplying the
LINK or to a pulsed output that is active when the LINK is powered
for the purpose of monitoring the LINK power status.
1
Link request. LREQ is an input from the LINK that requests the PHY
to perform some service.
23
Link interface isolation input. This pin controls the operation of output
differentiation logic on the CTLn and Dn pin. If an optional isolation
barrier of the type described in Annex J of IEEE 1394-1995 is
implement between the PHY and LLC. This pin should be tied low to
enable the internal differentiation logic.
3,4
Control I/O. the CTLn pins are bi-directional communications control
signals between the PHY and LLC.
5, 6, 8, 9, 10, Data I/O. The D terminals are bi-directional and pass data between the
11, 12, 13 PHY and LLC.
63
System clock. SYSCLK provides a 49.152 MHZ clock signal, which is
synchronized with the data transfers to the LLC.
36, 35
Port1, cable pair A. TPA1 is the port A connection to the twisted-pair
cable .Board traces from each pair of positive and negative differential
signal pins should be kept matched and as short as possible to the
external load resistors and to the cable connector
41, 40
Port2, cable pair A. TPA2 is the port A connection to the twisted-pair
cable .Board traces from each pair of positive and negative differential
signal pins should be kept matched and as short as possible to the
external load resistors and to the cable connector
47, 46
Port3, cable pair A. TPA3 is the port A connection to the twisted-pair
cable .Board traces from each pair of positive and negative differential
signal pins should be kept matched and as short as possible to the
external load resistors and to the cable connector
34, 33
Port1, cable pair B. TPB1 is the port B connection to the twisted-pair
cable .Board traces from each pair of positive and negative differential
signal pins should be kept matched and as short as possible to the
external load resistors and to the cable connector
39, 38
Port2, cable pair B. TPB2 is the port B connection to the twisted-pair
cable .Board traces from each pair of positive and negative differential
signal pins should be kept matched and as short as possible to the
external load resistors and to the cable connector
45, 44
Port3, cable pair B. TPB3 is the port B connection to the twisted-pair
cable .Board traces from each pair of positive and negative differential
signal pins should be kept matched and as short as possible to the
external load resistors and to the cable connector
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RTL8801 Preliminary
TPBIAS1
TPBIAS2
TPBIAS3
O
PC0-PC2
I
XI
XO
PLLGND
-
PLLVDD
AVDD
-
AVSS
-
BTSET
I
PDISABLE
I
DVDD
-
DVSS
-
RESET\
I
TEST1
I
TEST2
I
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Portn, twisted pair bias. It provides the 1.86-V nominal bias voltage
needed for proper operation of the twisted-pair cable drivers and
receivers and for sending a valid cable connection signal to the remote
nodes.
20, 21, 22 Power class indicators. The PC signals set the bit values of the three
power-class bits in the Self-ID packet (bit 21, 22 and 23). These bits
can be programmed by tying the terminals to VDD or to GND.
59, 60
Crystal oscillator. XI and XO connect to a 24.576 MHz parallel
resonant fundamental mode crystal
52, 56
PLL circuit ground. These pins should be tied together to the low
impedance ground plane
51
PLL circuit power. PLLVDD supplies power to the PLL circuit
30,31,43,50. Analog power. AVDD supplies power to the analog port of the device
37, 42, 48
32,49,53,54 Analog ground. These pins should be tied together to the low
impedance ground plane
55
Current Setting Resistor input. This pin is connected to an external
resistor to set the internal operating current and cable driver output
current
19
Port configuration monitor input. The pin is only active in power on
stage and meets the requirement of Open HCI.
7,17,26,57, Digital power. DVDD supplies power to the digital port of the device
62
2,14, 25,29, Digital Ground. These pins should be tied together to the low
58,64
impedance ground plane
61
Reset. An external capacitor in parallel with a resistor are required for
proper power-up operation
28
Test control input. This pin is used in the manufacturing test of the
device. For normal use it should be tied to DVSS.
27
Test control input. This pin is used in the manufacturing test of the
device. For normal use it should be tied to DVDD.
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RTL8801 Preliminary
5. Functional Block Diagram
CPS
Received
Data
Decoder/
Retimer
LPS
ISO\
SYS
CLK
Bias Voltage
and Current
Generator
TPBIAS1
TPBIAS2
TPBIAS3
LREQ
CTL0
Link
Interfac
e I/O
TPA1+
TPA1-
CTL1
D0
D1
D2
D3
D4
D5
D6
D7
Cable Port 1
Arbitration
and Control
State
Machine
Logic
PC0
PC1
PC2
TPB1+
TPB1-
Cable Port 2
TPB2+
TPB2-
C/LKON
TESTM1
TESTM2
Cable Port 3
RESET\
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TPA2+
TPA2-
Transmit
Data
Encoder
Crystal
Oscillator,
PLL System,
and Clock
Generator
TPA3+
TPA3TPB3+
TPB3-
XI
XO
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RTL8801 Preliminary
6. Functional Description
The operation of the cable PHY can best be understood with reference to the 5.0 block diagram
show before.
The main controller of the cable PHY is the block labeled “” arbitration and control state machine
logic” which responds to arbitration requests from the link layer and changes in the state of attached
ports. It provides the management and timing signals for transmitting, receiving, and repeating
packets. It also provides the bus reset and configuration . The cable environment supports the
immediate, fair, isochronous, and cycle_master arbitration classes, where the cycle_master class is
only available at the root node as described in IEEE1394 stnadard.
Cable arbitration has two parts: a three-phase initialization process (bus reset, tree identify, and
self-identify), and a normal operation phase. Each of these four phases is described using a state
machine, The state machine and the list of actions and conditions are the normative part of IEEE
1394 standard.
The“receive data decoder/retimer” block decodes the data -strobe signal and retimes the received
data to a local fixed-frequency clock provided by the local clock. Since the clocks of receiving and
transmitting nodes can be up to 100 ppm different from the nominal, the data resynch function has
to be able to compensate for a difference of 200 ppm over the maximum packet length of 84.31 us
(1024 byte isochronous packet at 98.304 Mbit/s). Data reception for the cable environment physical
layer has three major functions: decoding the data-strobe signal to recover a clock, synchronizing
the data to a local clock for use by the link layer, repeating the synchronized data out all other
connected ports.
The “”transmit data encoder” block provides a common interface to the link layer for both packet
data and arbitration signal (gaps and bus reset indicators). Data transmission is a straightforward
function: the data bits are sent to the attached peer PHY along with the appropriately encoded
strobe signal using the timing provided by the PHY transmit clock. If connected port cannot accept
data at the requested speed, then no data is send (leaving the drivers in the “01” data pr efix
condition).
The “”link interface” block provides a scalable, cost -effective method to connect one serial bus link
chip to one serial bus PHY chip. The width of the data bus scales with the highest speed both chips
can support, using two pins per 100 Mbit/s. The clock rate of the signals at this interface remains
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RTL8801 Preliminary
constant, independent of speed, to support galvanic isolation for implementations where it is
desirable. The PHY has control over the bidirectional pins. The link only drives these pins when
control is transferred to it by the PHY. The link performs all unsolicited activity through a
dedicated request pin. The possible actions that may occur on the interface are categorized as
transmit, receive, status, and request.
7. Internal Register Configuration
There are 16 accessible internal registers in the PHY. The configuration of the Register at
addresses 0h to7h is fixed. The register 8h to Fh are an index register window whose contents
change based upon the Page_Slect and Port_Select field in Register 7h.
7.1 PHY register field map for the cable environment
address
0
1
2
0000b
0001b
3
4
5
Physical_ID
RHB
IBR
6
7
R
PS
Gap_count
0010b
Extended(111b)
reserved
Total_ports(0011b)
0011b
Max_speed(010b)
reserved
Delay(0000b)
0100b
Link_
active
Conten
der
0101b
Resume_ ISBR
int
Jitter(000b)
Loop
0110b
0111b
1000b
Pwr_fail Time
out
Pwr_class
Port_event Enab_ Enab_
accel multi
Reserved
Page_select
reserved
Port_select
Register0(page_select)
……..
…….
1111b
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Register7(page_select)
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RTL8801 Preliminary
PHY register fields map for the cable environment
Field
size
type Power description
reset
value
Physical_ID
6
r
-
The address of this node determined during self-identification. A
value of 63 indicates a malconfigured bus; the link shall not
transmit any packets.
R
1
r
-
When set to one, indicate that this node is the root.
PS
1
r
-
Cable Power status.
RHB
1
rw
0
Root hold-off bit. When set to one, instructs the PHY to attempt
to become the root during the next tree identify process.
IBR
1
rw
0
Initiate bus reset. When set to one, instructs the PHY to initiate a
bus reset immediately (without arbitration). This bit causes
assertion of the reset state for 166 us and is self-clearing.
Gap_count
6
rw
3F
Used to configure the arbitration timer setting in order to
optimize gap times according to the topology of the bus. IEEE
1394-1995 4.3.6
Extended
3
r
7
constant value of seven, which indiactes extended PHY register
map is implemented
Total_ports
5
r
3
the number of ports implemented by this PHY
Max_speed
3
r
010
Indicates the maximum speed this PHY supports;
000 - 98.304 Mbit/s
001 - 98.304 and 196.608 Mbit/s
010 - 98.304 ,196.60 and 393.216 Mbit/s
011 – Up to786.43 Mbit/s
100 – Up to1,572.864 Mbit/s
101 – Up to 3,145.728 Mbit/s
Delay
4
r
0
Worse case repeater delay, expressed as 144+(delay*20)ns.
Link_active
1
rw
1
Link enabled. Default value of one subsequent to a power reset.
Otherwise cleared or set by software to control the value of the
L bit transmitted in the self-ID packet. The transmitted L bit
shall be the logical AND of this bit and the LPS signal.
Contender
1
rw
Pin
Contender. Cleared or set by software to control the value of the
C/LK C bit transmitted in the self-ID packet.
ON
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RTL8801 Preliminary
Pwr_class
3
rw
Pin
Power class. Controls the value of the pwr field transmitted in
PC0-P the self-ID packet.
C2
000 - Node does not need power and does not repeat
power
001 - Node is self-powered and provides a minimum of 15
W to the bus
010 - Node is self-powered and provides a minimum of 30
W to the bus.
011 - Node is self-powered and provides a minimum of 45
W to the bus
100 - Node may be powered from the bus and is using up
to 1 W.
101 - Node is powered from the bus and is using up to 1
W. An additional 2 W is needed to enable the link and
higher layers.
110 - Node is powered form the bus and is using up to 1
W. An additional 5 W is needed to enable the link and
higher layers.
111 - Node is powered from the bus and is using up to 1
W. An additional 9 W is needed to enable the link and
higher layers.
Jitter
3
r
0
The difference between the fastest and slowest repeater data
delay, expressed as (jitter+1)*20ns
Resume_int
1
rw
0
Resume interrupt enable. When set to one, the PHY shall set
port_event to one if resume operations commence for any port.
ISBR
1
rw
0
Initiate short (arbitrated) bus reset. A write of one to this bit
instructs the PHY to arbitrate and issue a short bus reset. This bit
is self-clearing.
Loop
1
rw
0
Loop detect. A write of one to this bit clears it to zero.
Pwr_fail
1
rw
0
Cable power failure detect. Set to one when the PS bit changes
from one to zero. A write of one to this bit clears it to zero.
Timeout
1
rw
0
Arbitration state machine timeout. A write of one to this bit
clears it to zero.
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Port_event
1
rw
0
Port event detect. The PHY sets this bit to one if any of
connected, Bias, Disabled or Fault change for a port whose
Int_enable bit is one. The PHY also sets this bit to one if resume
operations commence for any port and Resume_int is one. A
write of one to this bit clears it to zero.
Enab_accel
1
rw
0
Enable arbitration acceleration. When set to one, the PHY shall
use the enhancements specification in P1394A.
Enab_multi
1
rw
0
Enable multi-speed packet concatenation. When set to one, the
Link shall signal the speed of all packets to the PHY.
Page_select
3
rw
000
Selects which of eight possible PHY register pages are
accessible through the window at PHY register address 1000b
through 1111b, inclusive.
Port_select
4
rw
0000 If the page selected by Page_select presents per port
information, this field selects which port’s registers are
accessible through the window at PHY register addressed 1000b
through 1111b, inclusive.
7.2.PHY register page0: Port Status page
The port Status page is used to access configuration and status information for each of the PHY’s
port. The port is selected by writing zero to Page_select and the desired port number to Port_select
in the PHY register at address 0111.
0
1000b
1
3
4
5
BStat
6
7
Bias Disabled
£ Y
£ Y
1010b
Child connected
£ Y
Negotiated_speed
Int_enable Fault
£ Y
£ Y
£ Y
£ Y £ Y £ Y
£ Y
£ Y
1011b
£ Y
£ Y
£ Y
£ Y
£ Y
£ Y
£ Y
£ Y
1100b
£ Y
£ Y
£ Y
£ Y
£ Y
£ Y
£ Y
£ Y
1101b
£ Y
£ Y
£ Y
£ Y
£ Y
£ Y
£ Y
£ Y
1110b
£ Y
£ Y
£ Y
£ Y
£ Y
£ Y
£ Y
£ Y
1111b
£ Y
£ Y
£ Y
£ Y
£ Y
£ Y
£ Y
£ Y
1001b
AStat
2
Note: £ Y
-Reserved
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RTL8801 Preliminary
PHY register port status page fields
Field
Size
Astat
2
r
-
TPA line State for the port
00 = invalid
01 =1
10 =0
11 =z
Bstat
2
r
-
(same encoding as Astat)
Child
1
r
-
If equal to one, the port is a child, else a parent. The
meaning of this bit is undefined from the time a bus reset is
detected until the PHY transitions to state T1:Child
Handshake during the tree identify process(see 4.4.2.2 in
IEEE Std 1394-1995)
Connected
1
r
0
If equal to one, the port is connected, else disconnected.
The value reported by this bit is filtered by hysteresis logic
to reduce multiple status changes caused by contact scrape
when a connector is inserted or removed.
Bias
1
r
-
If equal to one, bias voltage is detected( possible
connection). The value reported by this bit is filtered by
hysteresis logic to reduce multiple status changes caused
by contact scrape when a connector is inserted or removed.
Disabled
1
rw
0
When set to one, the port shall be disabled. The value of
this
bit
subsequent
to
a
power
reset
is
implementation-dependent, but should be a strappable
option.
Negotiated_
speed
3
r
-
Indicated the maximum speed negotiated between this
PHY port and its immediately connected port; the encoding
is
000 – 98.304Mbit/s
001 - 196.608 Mbit/s
010 - 393.216 Mbit/s
1999/3
Type Power Description
reset
value
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RTL8801 Preliminary
Int_Enable
1
rw
0
Enable port event interrupts. When set to one, the PHY
shall set Port_event to one if any of Connected, Bias,
Disabled or Fault (for this port) change state.
Fault
1
Rw 0
Set to one if an error is detected during a suspend or
resume operation. A write of one to this bit clears it to zero.
7.3 PHY register page 1: Vendor identification page
The Vendor Identification page is used to identify the PHY’s vendor and compliance level. The
page is selected by writing one to Page_select in the PHY register at address 0111.
0
1
2
3
4
1000b
Compliance_level
1001b
Reserved
1010b
Vendor_ID
5
6
7
1011b
1100b
1101b
Product_ID
1110b
1111b
PHY register Vendor Identification page fields
Size
Type Description
Compliance
_level
8
R
Standard to which the PHY implementation complies:
0 = not specified
1 = IEEE P1394a
All other values reserved for future standardization. The
default is “1”.
Vendor_ID
24
R
The company ID or Organizationally Unique Identifier
(OUI) of the manufacturer of the PHY. The most
significant byte of Vendor_ID appears at PHY register
location 1010 and the least significant at 1100. The default
value is “00 e0 4c”.
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RTL8801 Preliminary
Product_ID
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24
R
The meaning of this number is determined by the company
or organization that has been granted Vendor_ID. The most
significant byte of Product_ID appears at PHY register
location 1101 and the least significant at 1111. The default
value is “88 01 00”.
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RTL8801 Preliminary
8.0 Application information
12 pF
12 pF
4.7k ohm
PGND
BVDD
PLLVDD
TGND
PLLGND
BGND
VDD
VDD
VDD
BTSET
ADVDD
PLLGND
XI
ADGND
XO
CTL0
TPA3-
CTL1
TPB3+
D0
TPB3-
D1
PVDD
DVDD
TPBIAS2
D2
TPA2+
RTL8801
D3
TPA2-
D4
TPB2+
D5
TPB2-
D6
TPBIAS1
D7
TPA1+
TP cable 3
VDD
TPBIAS2
TP cable
2
RGND
TPBIAS
1
TP cable
1
VDD
RVDD
TVDD
VDD
AGND
TEST1
TEST2
VDD
DXVDD
CPS
DXVSS
TPBIAS
3
68k ohm
390k ohm
CABLE
Power
LKON
VDD
BUS
MANAGER
ISO\
TPB1-
PC2
LPS
PC1
TPB1+
PC0
TPA1-
LACT
PDISABLE
DVSS
10k ohm
1999/3
RESET\
SCLK
TPA3+
DVDD
Link act
LLC or VDD
TPBIAS3
PDISABLE
power class
power class
power class
ISO
LLC
LLC
LLC
LLC
VDD
LLC
LLC
LLC
LLC
LLC
LLC
LREQ
DVSS
LKON/C
LLC
DVDD
DVSS
LLC
VDD
0.1uF
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RTL8801 Preliminary
9. ELECTRICAL CHARACTERISTICS
9.1. Absolute Maximum Ratings
Stresses in excess of the limits may cause permanent damage to the device. The device is not guaranteed
to function at these limits.
Parameter
Supply Voltage
Input voltage
Output voltage
Operating Temperature
Storage Temp.
Symbol
VDD
Vi
Vo
Top
Tstg
Min.
3
-0.5
-0.5
0
-65
Max.
3.6
VDD+0.5
VDD+0.5
70
150
Unit
V
V
V
¢J
¢J
Min.
3.0
0.8VDD
Type.
3.3
Max
3.6
9.2. Operating Conditions
Parameter
Supply voltage
High level input voltage
Low level input voltage
High level output voltage
Low level output voltage
Power-up reset time
Differential output voltage
Differential input voltage during
arbitration
Differential input voltage during
data reception
Power dissipation
Free air temperature
Symbol
VDD
VIIH
VIL
VOH
VOL
TRST
VOD
VIR
2
172
168
265
265
Unit
V
V
V
V
V
ms
mV
mV
VID
118
260
mV
PD
Top
0
0.55
70
W
¢J
0.2VDD
2.6
0.4
9.3 Link-PHY Interface Timing
SYSCLK
Dn, CTLn, LREQ
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Th
Tsu
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RTL8801 Preliminary
Parameter
Setup time, Dn, CTLn,
LREQ to Sysclk
Hold time, Dn, CTLn,
LREQ before Sysclk
Symbol
Tsu
Th
Min
5
2
Type.
Max.
Units
ns
ns
10. Outline Diagrams
64 -Pin LQFP
1999/3
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RTL8801 Preliminary
Note:
1.To be determined at seating plane
-c-
2.Dimensions D1 and E1 do not include mold
Symbol
Dimension
in
Dimension
inch
in
mm
Min Nom Max Min Nom Max
A
-
-
protrusion. D1 and E1 are maximum plastic body
0.067
-
-
1.70
0.1
0.20
size dimensions including mold mismatch.
3.Dimension b does not include dambar protrusion.
A1
0.000 0.004 0.008 0.00
Dambar can not be located on the lower radius of the foot.
A2
0.051 0.055 0.059 1.30 1.40 1.50
4.Exact shape of each corner is optional.
b
0.006 0.009 0.011 0.15 0.22 0.29
5.These dimensions apply to the flat section of the lead
b1
0.006 0.008 0.010 0.15 0.20 0.25
c
0.004
-
0.008 0.09
-
0.20
c1
0.004
-
0.006 0.09
-
0.16
between 0.10 mm and 0.25 mm from the lead tip.
6. A1 is defined as the distance from the seating plane
to the lowest point of the package body.
D
0.472 BSC
12.00 BSC
7.Controlling dimension : millimeter.
D1
0.394 BSC
10.00 BSC
8. Reference document : JEDEC MS-026 , BBC
E
0.472 BSC
12.00 BSC
TITLE : 64LD LQFP ( 10x10x1.4mm)
E1
0.394 BSC
10.00 BSC
PACKAGE OUTLINE DRAWING , FOOTPRINT 2.0mm
e
0.020 BSC
0.50 BSC
L
L1
LEADFRAME MATERIAL:
0.016 0.024 0.031 0.40 0.60 0.80
0.039 REF
APPROVE
1.00 REF
VERSION
θ
0°
3.5°
9°
0°
3.5°
9°
θ1
0°
-
-
0°
-
-
θ2
12° TYP
12° TYP
θ3
12° TYP
12° TYP
DOC. NO.
PAGE
CHECK
DWG NO.
DATE
1
OF
LQ064 - P1
NOV. 06.1997
REALTEK SEMI-CONDUCTOR CO., LTD
REALTEK Semiconductor Co., Ltd. reserved all rights of this document. No part of this
document may be copied or reproduced in any form or by any means or transferred to any third
party without the prior written consent of REALTEK Semiconductor Co., Ltd. REALTEK
reserves the right to change products or specifications without notice. This document has been
carefully checked and is believed to be accurate. However REALTEK Semiconductor Co., Ltd.
assumes no responsibility for inaccuracies.
1999/3
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RTL8801 Preliminary
1999/3
19