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DS80PCI800
SNLS334G – APRIL 2011 – REVISED JANUARY 2015
DS80PCI800 2.5-Gbps / 5.0-Gbps / 8.0-Gbps 8-Channel PCI-Express™
Repeater With Equalization and De-Emphasis
1 Features
2 Applications
•
•
1
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•
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•
•
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Comprehensive Family, Proven System
Interoperability
– DS80PCI102 : x1 PCIe
Gen-1, Gen-2, and Gen-3
– DS80PCI402 : x4 PCIe
Gen-1, Gen-2, and Gen-3
– DS80PCI800 : x8/x16 PCIe
Gen-1, Gen-2, and Gen-3
Automatic Rate Detect and Adaptation to Gen1/2/3 Speeds
Seamless Support for Gen-3 Transmit FIR
Handshake
Receiver EQ (up to 36 dB), Transmit DeEmphasis (up to 12 dB)
Adjustable Transmit VOD: 0.8 to 1.3 Vp-p (Pin
Mode)
0.2 UI of Residual Deterministic Jitter at 8 Gbps
After 40 Inches of FR4 or 10 m 30-awg PCIe
Cable
Low Power Dissipation With Ability to Turn Off
Unused Channels: 65 mW/Channel
Automatic Receiver Detect (Hot-Plug)
Multiple Configuration Modes: Pins/SMBus/DirectEEPROM Load
Flow-Thru Pinout: 54-Pin WQFN (10-mm ×
5.5-mm, 0.5-mm Pitch)
Single Supply Voltage: 2.5 or 3.3 V (Selectable)
±3 kV HBM ESD Rating
−40°C to 85°C Operating Temperature Range
PCI Express Gen-1, Gen-2, and Gen-3
3 Description
The DS80PCI800 is a low-power, 8-channel repeater
with 4-stage input equalization, and an output deemphasis driver to enhance the reach of PCI-Express
serial links in board-to-board or cable interconnects.
This device is ideal for higher density x8 and x16
PCI-Express configurations, and it automatically
detects and adapts to Gen-1, Gen-2, and Gen-3 data
rates for easy system upgrade.
DS80PCI800 offers programmable transmit deemphasis (up to 12 dB), transmit VOD (up to
1300 mVp-p) and receive equalization (up to 36 dB)
to enable longer distance transmission in lossy
copper cables (10 meters or more), or backplanes
(40 inches or more) with multiple connectors. The
receiver can open an input eye that is completely
closed due to inter-symbol interference (ISI)
introduced by the interconnect medium.
The programmable settings can be applied easily
through pins or software (SMBus/I2C), or can be
loaded through an external EEPROM. When
operating in the EEPROM mode, the configuration
information is automatically loaded on power up,
which eliminates the need for an external
microprocessor or software driver.
Device Information(1)
PART NUMBER
PACKAGE
DS80PCI800
BODY SIZE (NOM)
WQFN (54)
10.00 mm × 5.50 mm
(1) For all available packages, see the orderable addendum at
the end of the data sheet.
Typical Application Block Diagram
Simplified Schematic Diagram
DS80PCI800
8
TX
.
.
.
Add-in Card
End Point
PCIe
Connector
INB_0+
INB_0-
.
.
.
.
.
.
INB_3+
INB_3-
8
RX
DS80PCI800
.
.
.
INA_0+
INA_0-
.
.
.
.
.
.
.
.
.
AD0
OUTA_0+
OUTA_0-
.
.
.
SMBus Slave Mode(1)
SMBus Slave Mode(1)
RXDET
AD1
RATE
AD2
RESERVED
RX
System Board
Root Complex
3.3V
DS80PCI800
(3)
PCIe
Connector
From PCIe
PRSNT signal
PRSNT
VIN (3.3 V)
10�F
a rd
Bo ce
Tra
VIN
SMBus Slave Mode(1)
ENSMB
(2)
SDA
SCL(2)
To SMBus/I2C
Host Controller
1�F
8
TX
READ_EN / SD_TH
ALL_DONE
.
.
.
OUTA_3+
OUTA_3-
AD3
8
.
.
.
OUTB_3+
OUTB_3-
INA_3+
INA_3-
Address straps
(pull-up to VIN or
pull-down to GND)(1)
OUTB_0+
OUTB_0-
VDD_SEL
VDD (2.5 V)
GND (DAP)
0.1�F (x5)
(1) Schematic shows connection for SMBus Slave Mode (ENSMB=1kohm to VDD)
For SMBus Master Mode or Pin Mode configuration, the connections are different.
(2) SMBus signals need to be pulled up elsewhere in the system.
(3) Schematic requires different connections for 2.5 V mode.
1
An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,
intellectual property matters and other important disclaimers. PRODUCTION DATA.
�DS80PCI800
SNLS334G – APRIL 2011 – REVISED JANUARY 2015
www.ti.com
Table of Contents
1
2
3
4
5
6
Features ..................................................................
Applications ...........................................................
Description .............................................................
Revision History.....................................................
Pin Configuration and Functions .........................
Specifications.........................................................
1
1
1
2
3
6
6.1
6.2
6.3
6.4
6.5
Absolute Maximum Ratings ...................................... 6
ESD Ratings.............................................................. 6
Recommended Operating Ratings............................ 6
Electrical Characteristics .......................................... 7
Electrical Characteristics — Serial Management Bus
Interface .................................................................. 10
6.6 Typical Characteristics ............................................ 11
7
8
Parameter Measurement Information ................ 12
Detailed Description ............................................ 13
8.1 Overview ................................................................. 13
8.2 Functional Block Diagram ....................................... 13
8.3 Feature Description................................................. 14
8.4 Device Functional Modes........................................ 16
8.5 Programming........................................................... 16
8.6 Register Maps ......................................................... 20
9
Application and Implementation ........................ 40
9.1 Application Information............................................ 40
9.2 Typical Application ................................................. 41
10 Power Supply Recommendations ..................... 43
10.1 3.3-V or 2.5-V Supply Mode Operation................. 43
10.2 Power Supply Bypassing ...................................... 44
11 Layout................................................................... 45
11.1 Layout Guidelines ................................................. 45
11.2 Layout Example .................................................... 45
12 Device and Documentation Support ................. 46
12.1
12.2
12.3
12.4
Device Support......................................................
Trademarks ...........................................................
Electrostatic Discharge Caution ............................
Glossary ................................................................
46
46
46
46
13 Mechanical, Packaging, and Orderable
Information ........................................................... 46
4 Revision History
Changes from Revision F (April 2013) to Revision G
•
2
Page
Added ESD Ratings table, Feature Description section, Device Functional Modes, Application and Implementation
section, Power Supply Recommendations section, Layout section, Device and Documentation Support section, and
Mechanical, Packaging, and Orderable Information section ................................................................................................. 1
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SNLS334G – APRIL 2011 – REVISED JANUARY 2015
5 Pin Configuration and Functions
PRSNT
VDD
DEMA1/SCL
DEMA0/SDA
ENSMB
EQB1/AD2
EQB0/AD3
51
50
49
48
47
46
DEMB0/AD1
53
52
DEMB1/AD0
54
DS80PCI800
54 Lead
Top View
SMBUS AND CONTROL
INB_0+
1
45
OUTB_0+
INB_0-
2
44
OUTB_0-
INB_1+
3
43
OUTB_1+
INB_1-
4
42
OUTB_1-
INB_2+
5
41
VDD
INB_2-
6
40
OUTB_2+
INB_3+
7
39
OUTB_2-
INB_3-
8
38
OUTB_3+
VDD
9
37
OUTB_3-
INA_0+
10
36
VDD
INA_0-
11
35
OUTA_0+
INA_1+
12
34
OUTA_0-
INA_1-
13
33
OUTA_1+
VDD
14
32
OUTA_1-
INA_2+
15
31
OUTA_2+
INA_2-
16
30
OUTA_2-
INA_3+
17
29
OUTA_3+
INA_3-
18
28
OUTA_3-
19
20
21
22
23
24
25
26
27
EQA1
EQA0
RATE
RXDET
RESERVED
VIN
VDD_SEL
SD_TH/READ_EN
ALL_DONE
DAP = GND
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Pin Functions (1) (2) (3) (4)
PIN
NAME
NO.
I/O, TYPE
DESCRIPTION
I, CML
Inverting and non-inverting differential inputs to bank B equalizer. A gated on-chip 50-Ω
termination resistor connects INB_n+ to VDD and INB_n- to VDD depending on the state
of RXDET. See Table 4
AC coupling required on high-speed I/O
DIFFERENTIAL HIGH SPEED I/Os
INB_0+,
INB_1+,
INB_2+,
INB_3+,
INB_0-,
INB_1-,
INB_2-,
INB_3-
1, 2, 3, 4,
5, 6, 7, 8
INA_0+,
INA_1+,
INA_2+,
INA_3+,
INA_0-,
INA_1-,
INA_2-,
INA_3-
10, 11, 12,
13, 15, 16,
17, 18
I, CML
Inverting and non-inverting differential inputs to bank A equalizer. A gated on-chip 50-Ω
termination resistor connects INA_n+ to VDD and INA_n- to VDD depending on the state
of RXDET. See Table 4
AC coupling required on high-speed I/O
OUTB_0+,
OUTB_1+,
OUTB_2+,
OUTB_3+,
OUTB_0-,
OUTB_1-,
OUTB_2-,
OUTB_3-
45, 44, 43,
42, 40, 39,
38, 37
O, CML
Inverting and non-inverting 50-Ω driver bank B outputs with de-emphasis. Compatible
with AC-coupled CML inputs.
OUTA_0+,
OUTA_1+,
OUTA_2+,
OUTA_3+,
OUTA_0-,
OUTA_1-,
OUTA_2-,
OUTA_3-
35, 34, 33,
32, 31, 30,
29, 28
O, CML
Inverting and non-inverting 50-Ω driver bank A outputs with de-emphasis. Compatible
with AC-coupled CML inputs.
CONTROL PINS — SHARED (LVCMOS)
ENSMB
48
System management bus (SMBus) enable pin
I, 4-LEVEL, Tie 1 k to VDD (2.5-V mode) or VIN (3.3 V-mode) = Register access SMBus slave mode
LVCMOS FLOAT = Read external EEPROM (master SMBUS mode)
Tie 1 kΩ to GND = Pin mode
ENSMB = 1 (SMBus SLAVE MODE)
SCL
50
I, 2-LEVEL,
In SMBus Slave Mode, this pin is the SMBus clock I/O. Clock input or open drain output.
LVCMOS,
External 2-kΩ to 5-kΩ pullup resistor to VDD or VIN recommended as per SMBus
O, open
interface standards. (5)
drain
SDA
49
I, 2-LEVEL,
In both SMBus Modes, this pin is the SMBus data I/O. Data input or open drain output.
LVCMOS,
External 2-kΩ to 5-kΩ pullup resistor to VDD or VIN recommended as per SMBus
O, open
interface standards. (5)
drain
AD0-AD3
54, 53, 47,
46
SMBus Slave Address Inputs. In both SMBus Modes, these pins are the user set SMBus
I, 4-LEVEL,
slave address inputs.
LVCMOS
External 1-kΩ pullup or pulldown recommended.
READ_EN / SD_TH
26
I, FLOAT
In SMBus Slave Mode, this pin is not used. Leave it floating.
ENSMB = FLOAT (SMBus MASTER MODE)
SCL
50
I, 2-LEVEL,
LVCMOS,
O, open
drain
SDA
49
I, 2-LEVEL,
In both SMBus Modes, this pin is the SMBus data I/O. Data input or open drain output.
LVCMOS,
External 2-kΩ to 5-kΩ pullup resistor to VDD or VIN recommended as per SMBus
O, open
interface standards. (5)
drain
AD0-AD3
54, 53, 47,
46
SMBus Slave Address Inputs. In both SMBus Modes, these pins are the user set SMBus
I, 4-LEVEL,
slave address inputs.
LVCMOS
External 1-kΩ pullup or pulldown recommended.
READ_EN
26
A logic low on this pin starts the load from the external EEPROM (6)
I, 2-LEVEL,
Once EEPROM load is complete (ALL_DONE = 0), this pin functionality remains as
LVCMOS
READ_EN. It does not revert to an SD_TH input.
(1)
(2)
(3)
(4)
(5)
(6)
4
Clock output when loading EEPROM configuration, reverting to SMBus clock input when
EEPROM load is complete (ALL_DONE = 0).
External 2-kΩ to 5-kΩ pullup resistor to VDD or VIN recommended as per SMBus
interface standards. (5)
LVCMOS inputs without the “FLOAT” conditions must be driven to a logic low or high at all times or operation is not verified.
Input edge rate for LVCMOS/FLOAT inputs must be faster than 50 ns from 10% to 90%.
For 3.3-V mode operation, VIN pin = 3.3 V and the VDD for the 4-level input is 3.3 V.
For 2.5-V mode operation, VDD pin = 2.5 V and the VDD for the 4-level input is 2.5 V.
SCL and SDA pins can be tied either to 3.3 V or 2.5 V, regardless of whether the device is operating in 2.5-V mode or 3.3-V mode.
When READ_EN is asserted low, the device attempts to load EEPROM. If EEPROM cannot be loaded successfully, for example due to
an invalid or blank hex file, the DS80PCI800 waits indefinitely in an unknown state where SMBus access is not possible. ALL_DONE pin
remains high in this situation.
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Pin Functions(1)(2)(3)(4) (continued)
PIN
NAME
ALL_DONE
NO.
27
I/O, TYPE
DESCRIPTION
O, 2LEVEL,
LVCMOS
Valid register load status output
HIGH = External EEPROM load failed or incomplete
LOW = External EEPROM load passed
ENSMB = 0 (PIN MODE)
EQA0, EQA1,
EQB0, EQB1
DEMA0, DEMA1,
DEMB0, DEMB1
20, 19, 46,
47
EQA[1:0] and EQB[1:0] control the level of equalization on the input pins. The pins are
active only when ENSMB is deasserted (low). The 8 channels are organized into two
I, 4-LEVEL, banks. Bank A is controlled with the EQA[1:0] pins and bank B is controlled with the
LVCMOS EQB[1:0] pins. When ENSMB goes high the SMBus registers provide independent
control of each channel. The EQB[1:0] pins are converted to SMBUS AD2/AD3 inputs.
See Table 2.
49, 50, 53,
54
DEMA[1:0] and DEMB[1:0] control the level of de-emphasis of the output driver. The
pins are only active when ENSMB is deasserted (low). The 8 channels are organized
into two banks. Bank A is controlled with the DEMA[1:0] pins and bank B is controlled
I, 4-LEVEL,
with the DEMB[1:0] pins. When ENSMB goes high the SMBus registers provide
LVCMOS
independent control of each channel. The DEMA[1:0] pins are converted to SMBUS
SCL/SDA and DEMB[1:0] pins are converted to AD0, AD1 inputs.
See Table 3.
CONTROL PINS — BOTH PIN AND SMBUS MODES (LVCMOS)
RATE
21
RATE control pin selects GEN 1,2 and GEN 3 operating modes.
Tie 1 kΩ to GND = GEN 1,2
I, 4-LEVEL,
FLOAT = AUTO Rate Select of Gen1/2 and Gen3 with de-emphasis
LVCMOS
Tie 20 kΩ to GND = GEN 3 without de-emphasis
Tied 1 kΩ to VDD = RESERVED
RXDET
22
The RXDET pin controls the receiver detect function. Depending on the input level, a 50
I, 4-LEVEL,
Ω or > 50 kΩ termination to the power rail is enabled.
LVCMOS
See Table 4.
RESERVED
23
I, FLOAT
VDD_SEL
25
I, LVCMOS
SD_TH
26
I, 4-LEVEL, Controls the internal Signal Detect Threshold.
LVCMOS See Table 5.
PRSNT
52
Cable Present Detect input. High when a cable is not present per PCIe Cabling Spec.
I, 2-LEVEL,
1.0. Puts part into low power mode. When LOW (normal operation) part is enabled.
LVCMOS
See Table 4.
Float (leave pin open) = Normal Operation
Controls the internal regulator
FLOAT = 2.5-V mode
Tie GND = 3.3-V mode
See Figure 14
POWER
VIN
24
Power
In 3.3-V mode, feed 3.3 V to VIN
In 2.5-V mode, leave floating
VDD
9, 14, 36,
41, 51
Power
Power supply pins
2.5-V mode, connect to 2.5-V supply
3.3-V mode, connect 0.1-µF capacitor to each VDD pin (output of LDO)
GND
DAP
Power
Ground pad (DAP - die attach pad)
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6 Specifications
6.1 Absolute Maximum Ratings (1) (2) (3)
MIN
MAX
UNIT
Supply voltage (VDD - 2.5-V mode)
–0.5
2.75
V
Supply voltage (VIN - 3.3-V mode)
–0.5
4.0
V
LVCMOS input/output voltage
–0.5
4.0
V
CML input voltage
–0.5
VDD + 0.5
V
CML input current
–30
30
mA
125
°C
260
°C
125
°C
Junction temperature
Lead temperature soldering (4 s)
(4)
Storage temperature, Tstg
(1)
(2)
(3)
(4)
–40
Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings
only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under Recommended
Operating Ratings. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
Maximum Numbers are specified for a junction temperature range of –40°C to 125°C. Models are validated to Maximum Operating
Voltages only.
If Military/Aerospace specified devices are required, contact the Texas Instruments Sales Office/ Distributors for availability and
specifications.
For soldering specifications: See application note SNOA549.
6.2 ESD Ratings
MAX
V(ESD)
(1)
(2)
Electrostatic
discharge
Human body model (HBM), per ANSI/ESDA/JEDEC JS-001, all pins (1)
±3000
Charged device model (CDM), per JEDEC specification JESD22-C101, all pins (2)
±1000
Machine model (MM), per JEDEC specification JESD22-A115-A
±200
UNIT
V
JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.
JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process.
6.3 Recommended Operating Ratings
MIN
NOM
MAX
UNIT
2.375
2.5
2.625
V
Supply voltage (3.3-V mode)
3.0
3.3
3.6
V
Ambient temperature
–40
25
85
°C
3.6
V
100
mVp-p
Supply voltage (2.5-V mode)
SMBus (SDA, SCL)
Supply noise up to 50 MHz
(1)
6
(1)
Allowed supply noise (mVp-p sine wave) under typical conditions.
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6.4 Electrical Characteristics
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
VDD = 2.5 V supply,
EQ Enabled,
VOD = 1.0 Vp-p,
RXDET = 1, PRSNT = 0
500
700
VIN = 3.3 V supply,
EQ Enabled,
VOD = 1.0 Vp-p,
RXDET = 1, PRSNT = 0
660
UNIT
POWER
PD
Power Dissipation
mW
900
mW
LVCMOS / LVTTL DC SPECIFICATIONS
VIH25
High-level input voltage
(PRSNT, READ_EN pins)
2.5-V Mode
2.0
VDD
VIH33
High-level input voltage
(PRSNT, READ_EN pins)
3.3-V Mode
2.0
VIN
VIL
Low-Level Input Voltage
(PRSNT, READ_EN pins)
0
0.8
VOH
High-level output voltage
(ALL_DONE pin)
IOH = −4 mA
VOL
Low-level output voltage
(ALL_DONE pin)
IOL = 4 mA
IIH
Input high current (PRSNT pin)
VIN = 3.6 V,
LVCMOS = 3.6 V
Input high current with internal
resistors (4–level input pin)
IIL
Input low current (PRSNT pin)
Input low current with internal
resistors (4-level input pin)
VIN = 3.6 V,
LVCMOS = 0 V
V
V
V
2.0
V
0.4
–15
15
20
150
–15
15
–160
–40
V
μA
μA
μA
μA
CML RECEIVER INPUTS (IN_n+, IN_n-)
RLRX-DIFF
RX differential return loss
0.05 to 1.25 GHz
–16
dB
1.25 to 2.5 GHz
–16
dB
2.5 to 4.0 GHz
–14
dB
0.05 to 2.5 GHz
–12
dB
RLRX-CM
RX common mode return loss
ZRX-DC
RX DC single-ended impedance Tested at VDD = 2.5 V
40
50
60
ZRX-DIFF-DC
RX DC differential mode
impedance
Tested at VDD = 2.5 V
80
100
120
ZRX-HIGH-IMP-
DC input common mode
impedance for V > 0
VID = 0 to 200 mV,
ENSMB = 0, RXDET = 0,
VDD = 2.5 V
Differential RX peak-to-peak
voltage (VID)
Tested at pins
2.5 to 4.0 GHz
DC-POS
VRX-DIFF-DC
–8
Ω
kΩ
1.2
SD_TH = float,
0101 pattern at 8 Gbps
Measured at pins
180
VRX-IDLE-DET-
SD_TH = float,
0101 pattern at 8 Gbps
Measured at pins
110
Signal detect deassert level for
electrical idle
Ω
50
VRX-SIGNAL-DET- Signal detect assert level for
active data signal
DIFF-PP
DIFF-PP
dB
V
mVp-p
mVp-p
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Electrical Characteristics (continued)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
0.8
1.0
1.2
UNIT
HIGH-SPEED OUTPUTS
VTX-DIFF-PP
VTX-DE-
Output voltage differential swing Differential measurement with OUT_n+
and OUT_n-,
terminated by 50 Ω to GND,
AC-Coupled, VID = 1.0 Vp-p,
DEM0 = 1, DEM1 = 0 (1)
TX de-emphasis ratio
RATIO_3.5
VTX-DE-RATIO_6
tTX-DJ
TX de-emphasis ratio
Deterministic Jitter
tTX-RJ
Random Jitter
Vp-p
VOD = 1.0 Vp-p,
DEM0 = 0, DEM1 = R
Gen 1 & 2 modes only
–3.5
VOD = 1.0 Vp-p,
DEM0 = R, DEM1 = R
Gen 1 & 2 modes only
–6
dB
dB
VID = 800 mV, PRBS15 pattern, 8.0
Gbps, VOD = 1.0 V,
EQ = 0x00, DE = 0 dB (no input or
output trace loss)
0.05
UIpp
VID = 800 mV, 0101 pattern, 8.0 Gbps,
VOD = 1.0 V,
EQ = 0x00, DE = 0 dB, (no input or
output trace loss)
0.3
ps RMS
tTX-RISE-FALL
TX rise/fall time
20% to 80% of differential output
voltage (2)
35
45
tRF-MISMATCH
TX rise/fall mismatch
20% to 80% of differential output
voltage (2)
0.01
RLTX-DIFF
TX differential return loss
0.05 to 1.25 GHz
–16
dB
1.25 to 2.5 GHz
–12
dB
2.5 to 4 GHz
–11
dB
0.05 to 2.5 GHz
–12
dB
–8
dB
RLTX-CM
TX common mode return loss
ZTX-DIFF-DC
DC differential TX impedance
VTX-CM-AC-PP
TX AC peak-peak common
mode voltage
VOD = 1.0 Vp-p,
DEM0 = 1, DEM1 = 0 (2)
ITX-SHORT
TX short circuit current limit
Total current the transmitter can supply
when shorted to VDD or GND
Absolute delta of DC common
mode voltage during L0 and
electrical idle
(2)
Absolute delta of DC common
mode voltgae between TX+ and
TX-
(2)
Max time to transition to
differential DATA signal after
IDLE
VID = 1.0 Vp-p, 8 Gbps
Max time to transition to IDLE
after differential DATA signal
VID = 1.0 Vp-p, 8 Gbps
6.2
tPLHD/PHLD
High-to-low and low-to-high
differential propagation delay
EQ = 0x00
(3)
200
tLSK
Lane-to-lane skew
T = 25°C, VDD = 2.5 V
25
tPPSK
Part-to-part propagation delay
skew
T = 25°C, VDD = 2.5 V
40
2.5 to 4 GHz
VTX-CM-DCACTIVE-IDLEDELTA
VTX-CM-DC-LINEDELTA
tTX-IDLE-DATA
tTX-DATA-IDLE
(1)
(2)
(3)
8
ps
0.1
UI
Ω
100
100
20
mVp-p
mA
100
mV
25
mV
3.5
ns
ns
ps
ps
ps
In GEN3 mode, the output VOD level is not fixed. It will be adjusted automatically based on the VID input amplitude level. The output
VOD level set by DEMA/B[1:0] in GEN3 mode is dependent on the VID level and the frequency content. The DS80PCI800 repeater in
GEN3 mode is designed to be transparent, so the TX-FIR (de-emphasis) is passed to the RX to support the PCIe GEN3 handshake
negotiation link training.
Parameter is characterized but not tested in production.
Propagation delay measurements will change slightly based on the level of EQ selected. EQ = 0x00 will result in the largest propagation
delays.
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Electrical Characteristics (continued)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
EQUALIZATION
DJE1
DJE2
DJE3
DJE4
DJE5
DJE6
Residual deterministic jitter at
8 Gbps
35” 4mils FR4,
VID = 0.8 Vp-p,
PRBS15, EQ = 0x1F,
DEM = 0 dB
0.14
Residual deterministic jitter at
5 Gbps
35” 4mils FR4,
VID = 0.8 Vp-p,
PRBS15, EQ = 0x1F,
DEM = 0 dB
0.1
Residual deterministic jitter at
2.5 Gbps
35” 4mils FR4,
VID = 0.8 Vp-p,
PRBS15, EQ = 0x1F,
DEM = 0 dB
0.05
Residual deterministic jitter at
8 Gbps
10 meters 30-awg cable,
VID = 0.8 Vp-p,
PRBS15, EQ = 0x2F,
DEM = 0 dB
0.16
Residual deterministic jitter at
5 Gbps
10 meters 30-awg cable,
VID = 0.8 Vp-p,
PRBS15, EQ = 0x2F,
DEM = 0 dB
0.1
Residual deterministic jitter at
2.5 Gbps
10 meters 30-awg cable,
VID = 0.8 Vp-p,
PRBS15, EQ = 0x2F,
DEM = 0 dB
0.05
UIpp
UIpp
UIpp
UIpp
UIpp
UIpp
DE-EMPHASIS (GEN 1,2 MODE ONLY)
DJD1
DJD2
Residual deterministic jitter at
2.5 Gbps and 5.0 Gbps
Residual deterministic jitter at
2.5 Gbps and 5.0 Gbps
10” 4mils FR4,
VID = 0.8 Vp-p,
PRBS15, EQ = 0x00,
VOD = 1.0 Vp-p,
DEM = −3.5 dB
0.1
20” 4mils FR4,
VID = 0.8 Vp-p,
PRBS15, EQ = 0x00,
VOD = 1.0 Vp-p,
DEM = –9 dB
0.1
UIpp
UIpp
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6.5 Electrical Characteristics — Serial Management Bus Interface
Over recommended operating supply and temperature ranges unless other specified.
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
SERIAL BUS INTERFACE DC SPECIFICATIONS
VIL
Data, clock input low voltage
VIH
Data, clock input high voltage
IPULLUP
Current through pullup resistor or
current source
VDD
Nominal bus voltage
ILEAK-Bus
Input leakage per bus segment
ILEAK-Pin
Input leakage per device pin
CI
Capacitance for SDA and SCL
RTERM
External termination resistance pull Pullup VDD = 3.3 V (1)
to VDD = 2.5 V ± 5% or 3.3 V ± 10%
Pullup VDD = 2.5 V (1)
2.1
High Power Specification
(1)
0.8
V
3.6
V
4
mA
2.375
3.6
V
–200
200
µA
–15
(1) (2)
µA
10
pF
(2) (3)
2000
Ω
(2) (3)
1000
Ω
SERIAL BUS INTERFACE TIMING SPECIFICATIONS
FSMB
Bus operating frequency
ENSMB = VDD (Slave Mode)
ENSMB = FLOAT (Master Mode)
tBUF
Bus free time between stop and
start condition
tHD:STA
Hold time after (repeated) start
condition. After this period, the first
clock is generated.
280
400
400
kHz
520
kHz
1.3
µs
0.6
µs
At IPULLUP, Max
tSU:STA
Repeated start condition setup time
0.6
µs
tSU:STO
Stop condition setup time
0.6
µs
tHD:DAT
Data hold time
0
ns
tSU:DAT
Data setup time
100
ns
tLOW
Clock low period
1.3
µs
tHIGH
Clock high period
(4)
50
µs
tF
Clock/data fall time
(4)
300
ns
tR
Clock/data rise time
(4)
300
ns
tPOR
Time in which a device must be
operational after power-on reset
(4) (5)
500
ms
(1)
(2)
(3)
(4)
(5)
10
0.6
Recommended value.
Recommended maximum capacitance load per bus segment is 400 pF.
Maximum termination voltage should be identical to the device supply voltage.
Compliant to SMBus 2.0 physical layer specification. See System Management Bus (SMBus) Specification Version 2.0, section 3.1.1
SMBus common AC specifications for details.
Specified by design. Parameter not tested in production.
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6.6 Typical Characteristics
640.0
1021
VDD = 2.625V
620.0
T = 25°C
VDD = 2.5V
600.0
VDD = 2.375V
1019
560.0
VOD (mVp-p)
PD (mW)
580.0
540.0
520.0
500.0
480.0
1016
1013
T = 25oC
460.0
1010
440.0
420.0
0.8
0.9
1
1.1
1.2
1.3
1007
2.375
VOD (Vp-p)
2.5
2.625
VDD (V)
Figure 1. Power Dissipation (PD) vs Output Differential
Voltage (VOD)
Figure 2. Output Differential Voltage (VOD = 1.0 Vp-p) vs
Supply Voltage (VDD)
1020
VDD = 2.5 V
VOD (mVp-p)
1018
1016
1014
1012
- 40
-15
10
35
60
85
TEMPERATURE (°C)
Figure 3. Output Differential Voltage (VOD = 1.0 Vp-p) vs Temperature
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7 Parameter Measurement Information
80%
80%
VOD = [Out+ - Out-]
0V
20%
20%
tRISE
tFALL
Figure 4. CML Output and Rise and Fall Transition Time
+
IN
0V
tPLHD
tPHLD
+
OUT
0V
-
Figure 5. Propagation Delay Timing Diagram
+
IN
0V
DATA
tIDLE-DATA
tDATA-IDLE
+
OUT
0V
DATA
IDLE
IDLE
Figure 6. Transmit IDLE-DATA and DATA-IDLE Response Time
tLOW
tR
tHIGH
SCL
tHD:STA
tBUF
tHD:DAT
tF
tSU:STA
tSU:DAT
tSU:STO
SDA
SP
ST
SP
ST
Figure 7. SMBus Timing Parameters
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8 Detailed Description
8.1 Overview
The DS80PCI800 provides input CTLE and output De-emphasis equalization for lossy printed circuit board trace
and cables. The DS80PCI800 operates in three modes: Pin Control Mode configuration (ENSMB = 0), SMBus
Slave Mode (ENSMB = 1) for register configurations from host controller or SMBus Master Mode (ENSMB =
Float) for loading the register configurations from an external EEPROM.
8.2 Functional Block Diagram
One of Four B Channels
INB_[3:0]+
OUTB_[3:0]+
EQ
Driver
INB_[3:0]-
OUTB_[3:0]Rate
Detect
Rx
Detect
Signal
Detect
Term
EQB[1:0]
DEMB[1:0]
RXDET
RATE
ALL_DONE
READ_EN
VDD (x5)
PRSNT
SCL
SDA
Internal
3.3 V to 2.5 V
Regulator
Digital Core and SMBus Registers
AD[3:0]
VIN
ENSMB
VDD_SEL
EQA[1:0]
DEMA[1:0]
Term
Rate
Detect
Signal
Detect
Rx
Detect
INA_[3:0]+
OUTA_[3:0]+
EQ
Driver
INA_[3:0]-
OUTA_[3:0]-
One of Four A Channels
Note: This diagram is representative of device signal flow only.
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8.3 Feature Description
8.3.1 4-Level Input Configuration Guidelines
The 4-level input pins use a resistor divider to help set the four valid levels. There is an internal 30-kΩ pullup and
a 60-kΩ pulldown connected to the package pin. These resistors, together with the external resistor connection
combine to achieve the desired voltage level. Using the 1-kΩ pullup, 1-kΩ pulldown, no connect, or 20-kΩ
pulldown provide the optimal voltage levels for each of the four input states.
Table 1. 4-Level Input Voltage
LEVEL
SETTING
3.3-V MODE
0
1 kΩ to GND
0.1 V
2.5-V MODE
0.08 V
R
20 kΩ to GND
0.33 × VIN
0.33 × VDD
F
FLOAT
0.67 × VIN
0.67 × VDD
1
1 kΩ to VDD/VIN
VIN – 0.05 V
VDD – 0.04 V
Typical 4-level input thresholds:
• Level 1 to 2 = 0.2 VIN or VDD
• Level 2 to 3 = 0.5 VIN or VDD
• Level 3 to 4 = 0.8 VIN or VDD
To minimize the start-up current associated with the integrated 2.5 V regulator, the 1-kΩ pullup and pulldown
resistors are recommended. If several 4-level inputs require the same setting, it is possible to combine two or
more 1-kΩ resistors into a single lower value resistor. As an example; combining two inputs with a single 500-Ω
resistor is a good way to save board space. For the 20 kΩ to GND, this should also scale to 10 kΩ.
Table 2. Equalizer Settings (1)
EQUALIZATION BOOST RELATIVE TO DC
LEVEL
EQA1
EQB1
1
2
(1)
14
EQA0
EQB0
EQ – 8 BITS [7:0]
dB at
1.25 GHz
dB at
2.5 GHz
dB at
4 GHz
SUGGESTED USE
0
0
0000 0000 = 0x00
2.1
3.7
4.9
FR4 < 5 inch trace
0
R
0000 0001 = 0x01
3.4
5.8
7.9
FR4 5 inch 5–mil trace
3
0
Float
0000 0010 = 0x02
4.8
7.7
9.9
FR4 5 inch 4-mil trace
4
0
1
0000 0011 = 0x03
5.9
8.9
11.0
FR4 10 inch 5–mil trace
5
R
0
0000 0111 = 0x07
7.2
11.2
14.3
FR4 10 inch 4-mil trace
6
R
R
0001 0101 = 0x15
6.1
11.4
14.6
FR4 15 inch 4-mil trace
7
R
Float
0000 1011 = 0x0B
8.8
13.5
17.0
FR4 20 inch 4-mil trace
8
R
1
0000 1111 = 0x0F
10.2
15.0
18.5
FR4 25 to 30 inch 4-mil trace
9
Float
0
0101 0101 = 0x55
7.5
12.8
18.0
FR4 30 inch 4-mil trace
10
Float
R
0001 1111 = 0x1F
11.4
17.4
22.0
FR4 35 inch 4-mil trace
11
Float
Float
0010 1111 = 0x2F
13.0
19.7
24.4
10 m, 30-awg cable
12
Float
1
0011 1111 = 0x3F
14.2
21.1
25.8
10 m – 12m cable
13
1
0
1010 1010 = 0xAA
13.8
21.7
27.4
14
1
R
0111 1111 = 0x7F
15.6
23.5
29.0
15
1
Float
1011 1111 = 0xBF
17.2
25.8
31.4
16
1
1
1111 1111 = 0xFF
18.4
27.3
32.7
The suggested equalizer CTLE settings are based on 0 dB of TX preshoot/de-emphasis. In PCIe Gen 3 applications which use TX
preshoot/de-emphasis, the CTLE should be set to a lower boost setting to optimize the RX eye opening.
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Table 3. Output Voltage and De-Emphasis Settings (1)
LEVEL
DEMA1
DEMB1
DEMA0
DEMB0
VOD Vp-p
DEM dB (1)
INNER AMPLITUDE
Vp-p
SUGGESTED USE
1
0
0
0.8
0
0.8
FR4 < 5 inch 4-mil trace
2
0
R
0.9
0
0.9
FR4 < 5 inch 4-mil trace
3
0
Float
0.9
–3.5
0.6
FR4 10 inch 4-mil trace
4
0
1
1.0
0
1.0
FR4 < 5 inch 4-mil trace
5
R
0
1.0
–3.5
0.7
FR4 10 inch 4-mil trace
6
R
R
1.0
–6
0.5
FR4 15 inch 4-mil trace
7
R
Float
1.1
0
1.1
FR4 < 5 inch 4-mil trace
8
R
1
1.1
–3.5
0.7
FR4 10 inch 4-mil trace
9
Float
0
1.1
–6
0.6
FR4 15 inch 4-mil trace
10
Float
R
1.2
0
1.2
FR4 < 5 inch 4-mil trace
11
Float
Float
1.2
–3.5
0.8
FR4 10 inch 4-mil trace
12
Float
1
1.2
–6
0.6
FR4 15 inch 4-mil trace
13
1
0
1.3
0
1.3
FR4 < 5 inch 4-mil trace
14
1
R
1.3
–3.5
0.9
FR4 10 inch 4-mil trace
15
1
Float
1.3
–6
0.7
FR4 15 inch 4-mil trace
16
1
1
1.3
–9
0.5
FR4 20 inch 4-mil trace
(1)
The VOD output amplitude and DEM de-emphasis levels are set with the DEMA/B[1:0] pins.
The de-emphasis levels are available in GEN1, GEN2, and GEN 3 modes when RATE = Float.
Table 4. RX-Detect Settings
(1)
PRSNT
(PIN 52)
RXDET
(PIN 22)
SMBus REG
BIT[3:2]
INPUT TERMINATION COMMENTS
0
0
00
Hi-Z
0
Tie 20 kΩ
to GND
01
Pre Detect: Hi-Z
Post Detect: 50 Ω
Auto RX-Detect, outputs test every 12 ms for 600 ms
then stops; termination is hi-Z until detection; once
detected input termination is 50 Ω
Reset function by pulsing PRSNT high for 5 µs then
low again
0
Float
(Default)
10
Pre Detect: Hi-Z
Post Detect: 50 Ω
Auto RX-Detect, outputs test every 12 ms until
detection occurs; termination is hi-Z until detection;
once detected input termination is 50 Ω
Reset function by pulsing PRSNT high for 5 µs then
low again
0
1
11
50 Ω
Manual RX-Detect, input is 50 Ω
1
X
Hi-Z
Power-down mode, input is high impedance, output
drivers are disabled
Manual RX-Detect, input is high-impedance mode
Used to reset RX-Detect State Machine when held
high for 5 µs
(1)
In SMBus Slave Mode, the Rx Detect State Machine can be manually reset in software by overriding the device PRSNT function. This is
accomplished by setting the Override RXDET bit (Reg 0x02[7]) and then toggling the RXDET Value bit (Reg 0x02[6]). See Table 9 for
more information about resetting the Rx Detect State Machine.
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Table 5. Signal Detect Threshold Level (1)
SD_TH
SMBus REG BIT [3:2] AND [1:0]
ASSERT LEVEL (TYP)
DEASSERT LEVEL (TYP)
0
10
210 mVp-p
150 mVp-p
R
01
160 mVp-p
100 mVp-p
F (default)
00
180 mVp-p
110 mVp-p
1
11
190 mVp-p
130 mVp-p
(1)
VDD = 2.5 V, 25°C, and 0101 pattern at 8 Gbps.
8.4 Device Functional Modes
The DS80PCI800 is a low-power 8-channel repeater optimized for PCI Express Gen 1/2 and 3. The DS80PCI800
compensates for lossy FR-4 printed circuit board backplanes and balanced cables. The DS80PCI800 operates in
three modes: Pin Control Mode (ENSMB = 0), SMBus Slave Mode (ENSMB = 1) and SMBus Master Mode
(ENSMB = float) to load register information from external EEPROM; refer to SMBus Master Mode for additional
information.
8.4.1 Pin Control Mode
When in pin mode (ENSMB = 0), equalization and de-emphasis can be selected via pin for each side
independently. When de-emphasis is asserted VOD is automatically adjusted per the De- Emphasis table below.
The RXDET pins provides automatic and manual control for input termination (50 Ω or > 50 kΩ). RATE setting is
also pin controllable with pin selections (Gen 1/2, auto detect and Gen 3). The receiver electrical idle detect
threshold is also adjustable via the SD_TH pin.
8.4.2 SMBUS Mode
When in SMBus mode (ENSMB = 1), the VOD (output amplitude), equalization, de-emphasis, and termination
disable features are all programmable on a individual lane basis, instead of grouped by A or B as in the pin mode
case. Upon assertion of ENSMB, the EQx and DEMx functions revert to register control immediately. The EQx
and DEMx pins are converted to AD0-AD3 SMBus address inputs. The other external control pins (RATE,
RXDET and SD_TH) remain active unless their respective registers are written to and the appropriate override bit
is set, in which case they are ignored until ENSMB is driven low (pin mode). On power-up and when ENSMB is
driven low all registers are reset to their default state. If PRSNT is asserted while ENSMB is high, the registers
retain their current state.
Equalization settings accessible via the pin controls were chosen to meet the needs of most PCIe applications. If
additional fine tuning or adjustment is needed, additional equalization settings can be accessed via the SMBus
registers. Each input has a total of 256 possible equalization settings. The 4-Level Input Configuration Guidelines
show the 16 setting when the device is in pin mode. When using SMBus mode, the equalization, VOD and deemphasis levels are set by registers.
8.5 Programming
8.5.1 System Management Bus (SMBus) and Configuration Registers
The System Management Bus interface is compatible to SMBus 2.0 physical layer specification. ENSMB = 1 kΩ
to VDD to enable SMBus slave mode and allow access to the configuration registers.
The DS80PCI800 has the AD[3:0] inputs in SMBus mode. These pins are the user set SMBUS slave address
inputs. The AD[3:0] pins have internal pulldown. When left floating or pulled low the AD[3:0] = 0000'b, the device
default address byte is 0xB0. Based on the SMBus 2.0 specification, the DS80PCI800 has a 7-bit slave address.
The LSB is set to 0'b (for a WRITE). The device supports up to 16 address byte, which can be set with the
AD[3:0] inputs. Below are the 16 addresses.
16
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Programming (continued)
Table 6. Device Slave Address Bytes
AD[3:0] SETTINGS
ADDRESS BYTES (HEX)
7-BIT SLAVE ADDRESS (HEX)
0000
B0
58
0001
B2
59
0010
B4
5A
0011
B6
5B
0100
B8
5C
0101
BA
5D
0110
BC
5E
0111
BE
5F
1000
C0
60
1001
C2
61
1010
C4
62
1011
C6
63
1100
C8
64
1101
CA
65
1110
CC
66
1111
CE
67
The SDA/SCL pins are 3.3 V tolerant, but are not 5 V tolerant. An external pullup resistor is required on the SDA
and SCL line. The resistor value can be from 2 kΩ to 5 kΩ depending on the voltage, loading, and speed.
8.5.2 Transfer of Data Through the SMBus
During normal operation the data on SDA must be stable during the time when SCL is High.
There are three unique states for the SMBus:
START: A high-to-low transition on SDA while SCL is High indicates a message START condition.
STOP: A low-to-high transition on SDA while SCL is High indicates a message STOP condition.
IDLE: If SCL and SDA are both High for a time exceeding tBUF from the last detected STOP condition or if they
are High for a total exceeding the maximum specification for tHIGH then the bus will transfer to the IDLE state.
8.5.3 Writing a Register
To
1.
2.
3.
4.
5.
6.
7.
write a register, the following protocol is used (see SMBus 2.0 specification).
The Host drives a START condition, the 7-bit SMBus address, and a “0” indicating a WRITE.
The Device (Slave) drives the ACK bit (“0”).
The Host drives the 8-bit Register Address.
The Device drives an ACK bit (“0”).
The Host drive the 8-bit data byte.
The Device drives an ACK bit (“0”).
The Host drives a STOP condition.
The WRITE transaction is completed, the bus goes IDLE and communication with other SMBus devices may
now occur.
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8.5.4 Reading a Register
To read a register, the following protocol is used (see SMBus 2.0 specification).
1. The Host drives a START condition, the 7-bit SMBus address, and a “0” indicating a WRITE.
2. The Device (Slave) drives the ACK bit (“0”).
3. The Host drives the 8-bit Register Address.
4. The Device drives an ACK bit (“0”).
5. The Host drives a START condition.
6. The Host drives the 7-bit SMBus Address, and a “1” indicating a READ.
7. The Device drives an ACK bit “0”.
8. The Device drives the 8-bit data value (register contents).
9. The Host drives a NACK bit “1”indicating end of the READ transfer.
10. The Host drives a STOP condition.
The READ transaction is completed, the bus goes IDLE and communication with other SMBus devices may now
occur.
8.5.5 SMBus Master Mode
The DS80PCI800 device supports reading directly from an external EEPROM device by implementing SMBus
Master mode. When using the SMBus master mode, the DS80PCI800 will read directly from specific location in
the external EEPROM. When designing a system for using the external EEPROM, the user needs to follow these
specific guidelines.
• Set ENSMB = Float — enable the SMBUS master mode.
• The external EEPROM device address byte must be 0xA0 and capable of 1 MHz operation at 2.5 V and 3.3
V supply. The maximum allowed size is 8 kbits (1024 bytes).
• Set the AD[3:0] inputs for SMBus address byte. When the AD[3:0] = 0000'b, the device address byte is 0xB0.
When tying multiple DS80PCI800 devices to the SDA and SCL bus, use these guidelines to configure the
devices.
• Use SMBus AD[3:0] address bits so that each device can loaded its configuration from the EEPROM.
Example below is for 4 devices.
– U1: AD[3:0] = 0000 = 0xB0
– U2: AD[3:0] = 0001 = 0xB2
– U3: AD[3:0] = 0010 = 0xB4
– U4: AD[3:0] = 0011 = 0xB6
• Use a pullup resistor on SDA and SCL; value = 2 kΩ
• Daisy-chain READ_EN (pin 26) and ALL_DONE (pin 27) from one device to the next device in the sequence
so that they do not compete for the EEPROM at the same time.
1. Tie READ_EN of the first device in the chain (U1) to GND
2. Tie ALL_DONE of U1 to READ_EN of U2
3. Tie ALL_DONE of U2 to READ_EN of U3
4. Tie ALL_DONE of U3 to READ_EN of U4
5. Optional: Tie ALL_DONE output of U4 to a LED to show the devices have been loaded successfully
18
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The following example represents a 2 kbits (256 × 8-bit) EEPROM in hex format for the DS80PCI800 device. The
first 3 bytes of the EEPROM always contain a header common and necessary to control initialization of all
devices connected to the SMBus. CRC enable flag to enable/disable CRC checking. If CRC checking is disabled,
a fixed pattern (0xA5) is written/read instead of the CRC byte from the CRC location, to simplify the control.
There is a MAP bit to flag the presence of an address map that specifies the configuration data start in the
EEPROM. If the MAP bit is not present the configuration data start address is derived from the DS80PCI800
address and the configuration data size. A bit to indicate an EEPROM size > 256 bytes is necessary to properly
address the EEPROM. There are 37 bytes of data size for each DS80PCI800 device.
:2000000000001000000407002FAD4002FAD4002FAD4002FAD401805F5A8005F5A8005F5AD8
:200020008005F5A800005454000000000000000000000000000000000000000000000000F6
:20006000000000000000000000000000000000000000000000000000000000000000000080
:20008000000000000000000000000000000000000000000000000000000000000000000060
:2000A000000000000000000000000000000000000000000000000000000000000000000040
:2000C000000000000000000000000000000000000000000000000000000000000000000020
:2000E000000000000000000000000000000000000000000000000000000000000000000000
:200040000000000000000000000000000000000000000000000000000000000000000000A0
For more information in regards to EEPROM programming and the hex format, see SNLA228.
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8.6 Register Maps
Table 7. EEPROM Register Map - Single Device with Default Value
EEPROM Address Byte
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
BIt 0
CRC EN
Address Map
Present
EEPROM > 256
Bytes
RES
DEVICE
COUNT[3]
DEVICE
COUNT[2]
DEVICE
COUNT[1]
DEVICE
COUNT[0]
0
0
0
0
0
0
0
0
RES
RES
RES
RES
RES
RES
RES
RES
0
0
0
0
0
0
0
0
Max EEPROM
Burst size[7]
Max EEPROM
Burst size[6]
Max EEPROM
Burst size[5]
Max EEPROM
Burst size[4]
Max EEPROM
Burst size[3]
Max EEPROM
Burst size[2]
Max EEPROM
Burst size[1]
Max EEPROM
Burst size[0]
0
0
0
0
0
0
0
0
PWDN_ch7
PWDN_ch6
PWDN_ch5
PWDN_ch4
PWDN_ch3
PWDN_ch2
PWDN_ch1
PWDN_ch0
0x01[7]
0x01[6]
0x01[5]
0x01[4]
0x01[3]
0x01[2]
0x01[1]
0x01[0]
0
0
0
0
0
0
0
0
Description
lpbk_1
lpbk_0
PWDN_INPUTS
PWDN_OSC
Ovrd_PRSNT
RES
RES
RES
SMBus Register
0x02[5]
0x02[4]
0x02[3]
0x02[2]
0x02[0]
0x04[7]
0x04[6]
0x04[5]
0
0
0
0
0
0
0
0
Description
RES
RES
RES
RES
RES
rxdet_btb_en
Ovrd_idle_th
Ovrd_RES
SMBus Register
0x04[4]
0x04[3]
0x04[2]
0x04[1]
0x04[0]
0x06[4]
0x08[6]
0x08[5]
0
0
0
0
0
1
0
0
Description
Ovrd_IDLE
Ovrd_RX_DET
Ovrd_RATE
RES
RES
rx_delay_sel_2
rx_delay_sel_1
rx_delay_sel_0
SMBus Register
0x08[4]
0x08[3]
0x08[2]
0x08[1]
0x08[0]
0x0B[6]
0x0B[5]
0x0B[4]
0
0
0
0
0
1
1
1
RD_delay_sel_3
RD_delay_sel_2
RD_delay_sel_1
RD_delay_sel_0
ch0_Idle_auto
ch0_Idle_sel
ch0_RXDET_1
ch0_RXDET_0
0x0B[3]
0x0B[2]
0x0B[1]
0x0B[0]
0x0E[5]
0x0E[4]
0x0E[3]
0x0E[2]
0
0
0
0
0
0
0
0
Description
0x00
Default
Value
0x00
Description
Default
Value
0x00
0x01
Description
0x02
Default
Value
0x00
Description
SMBus Register
Default
Value
0x03
0x00
Default
Value
0x04
0x00
Default
Value
0x05
0x04
Default
Value
0x06
0x07
Description
SMBus Register
Default
Value
20
0x00
0x07
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Register Maps (continued)
Table 7. EEPROM Register Map - Single Device with Default Value (continued)
EEPROM Address Byte
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
BIt 0
Description
ch0_BST_7
ch0_BST_6
ch0_BST_5
ch0_BST_4
ch0_BST_3
ch0_BST_2
ch0_BST_1
ch0_BST_0
SMBus Register
0x0F[7]
0x0F[6]
0x0F[5]
0x0F[4]
0x0F[3]
0x0F[2]
0x0F[1]
0x0F[0]
0
0
1
0
1
1
1
1
Description
ch0_Sel_scp
ch0_Sel_mode
ch0_RES_2
ch0_RES_1
ch0_RES_0
ch0_VOD_2
ch0_VOD_1
ch0_VOD_0
SMBus Register
0x10[7]
0x10[6]
0x10[5]
0x10[4]
0x10[3]
0x10[2]
0x10[1]
0x10[0]
1
0
1
0
1
1
0
1
Description
ch0_DEM_2
ch0_DEM_1
ch0_DEM_0
ch0_Slow
ch0_idle_tha_1
ch0_idle_tha_0
ch0_idle_thd_1
ch0_idle_thd_0
SMBus Register
0x11[2]
0x11[1]
0x11[0]
0x12[7]
0x12[3]
0x12[2]
0x12[1]
0x12[0]
0
1
0
0
0
0
0
0
Description
ch1_Idle_auto
ch1_Idle_sel
ch1_RXDET_1
ch1_RXDET_0
ch1_BST_7
ch1_BST_6
ch1_BST_5
ch1_BST_4
SMBus Register
0x15[5]
0x15[4]
0x15[3]
0x15[2]
0x16[7]
0x16[6]
0x16[5]
0x16[4]
0
0
0
0
0
0
1
0
ch1_BST_3
ch1_BST_2
ch1_BST_1
ch1_BST_0
ch1_Sel_scp
ch1_Sel_mode
ch1_RES_2
ch1_RES_1
0x16[3]
0x16[2]
0x16[1]
0x16[0]
0x17[7]
0x17[6]
0x17[5]
0x17[4]
1
1
1
1
1
0
1
0
Description
ch1_RES_0
ch1_VOD_2
ch1_VOD_1
ch1_VOD_0
ch1_DEM_2
ch1_DEM_1
ch1_DEM_0
ch1_Slow
SMBus Register
0x17[3]
0x17[2]
0x17[1]
0x17[0]
0x18[2]
0x18[1]
0x18[0]
0x19[7]
1
1
0
1
0
1
0
0
Description
ch1_idle_tha_1
ch1_idle_tha_0
ch1_idle_thd_1
ch1_idle_thd_0
ch2_Idle_auto
ch2_Idle_sel
ch2_RXDET_1
ch2_RXDET_0
SMBus Register
0x19[3]
0x19[2]
0x19[1]
0x19[0]
0x1C[5]
0x1C[4]
0x1C[3]
0x1C[2]
0
0
0
0
0
0
0
0
Description
ch2_BST_7
ch2_BST_6
ch2_BST_5
ch2_BST_4
ch2_BST_3
ch2_BST_2
ch2_BST_1
ch2_BST_0
SMBus Register
0x1D[7]
0x1D[6]
0x1D[5]
0x1D[4]
0x1D[3]
0x1D[2]
0x1D[1]
0x1D[0]
0
0
1
0
1
1
1
1
Default
Value
Default
Value
Default
Value
Default
Value
0x08
0x2F
0x09
0xAD
0x0A
0x40
0x0B
0x02
Description
SMBus Register
Default
Value
Default
Value
Default
Value
Default
Value
0x0C
0xFA
0x0D
0xD4
0x0E
0x00
0x2F
0x0F
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Register Maps (continued)
Table 7. EEPROM Register Map - Single Device with Default Value (continued)
EEPROM Address Byte
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
BIt 0
Description
ch2_Sel_scp
ch2_Sel_mode
ch2_RES_2
ch2_RES_1
ch2_RES_0
ch2_VOD_2
ch2_VOD_1
ch2_VOD_0
SMBus Register
0x1E[7]
0x1E[6]
0x1E[5]
0x1E[4]
0x1E[3]
0x1E[2]
0x1E[1]
0x1E[0]
1
0
1
0
1
1
0
1
Description
ch2_DEM_2
ch2_DEM_1
ch2_DEM_0
ch2_Slow
ch2_idle_tha_1
ch2_idle_tha_0
ch2_idle_thd_1
ch2_idle_thd_0
SMBus Register
0x1F[2]
0x1F[1]
0x1F[0]
0x20[7]
0x20[3]
0x20[2]
0x20[1]
0x20[0]
0
1
0
0
0
0
0
0
Description
ch3_Idle_auto
ch3_Idle_sel
ch3_RXDET_1
ch3_RXDET_0
ch3_BST_7
ch3_BST_6
ch3_BST_5
ch3_BST_4
SMBus Register
0x23[5]
0x23[4]
0x23[3]
0x23[2]
0x24[7]
0x24[6]
0x24[5]
0x24[4]
0
0
0
0
0
0
1
0
Description
ch3_BST_3
ch3_BST_2
ch3_BST_1
ch3_BST_0
ch3_Sel_scp
ch3_Sel_mode
ch3_RES_2
ch3_RES_1
SMBus Register
0x24[3]
0x24[2]
0x24[1]
0x24[0]
0x25[7]
0x25[6]
0x25[5]
0x25[4]
1
1
1
1
1
0
1
0
ch3_RES_0
ch3_VOD_2
ch3_VOD_1
ch3_VOD_0
ch3_DEM_2
ch3_DEM_1
ch3_DEM_0
ch3_Slow
0x25[3]
0x25[2]
0x25[1]
0x25[0]
0x26[2]
0x26[1]
0x26[0]
0x27[7]
1
1
0
1
0
1
0
0
Description
ch3_idle_tha_1
ch3_idle_tha_0
ch3_idle_thd_1
ch3_idle_thd_0
ovrd_fast_idle
en_high_idle_th_n en_high_idle_th_s
en_fast_idle_n
SMBus Register
0x27[3]
0x27[2]
0x27[1]
0x27[0]
0x28[6]
0x28[5]
0x28[4]
0x28[3]
0
0
0
0
0
0
0
1
Description
en_fast_idle_s
eqsd_mgain_n
eqsd_mgain_s
ch4_Idle_auto
ch4_Idle_sel
ch4_RXDET_1
ch4_RXDET_0
ch4_BST_7
SMBus Register
0x28[2]
0x28[1]
0x28[0]
0x2B[5]
0x2B[4]
0x2B[3]
0x2B[2]
0x2C[7]
1
0
0
0
0
0
0
0
Description
ch4_BST_6
ch4_BST_5
ch4_BST_4
ch4_BST_3
ch4_BST_2
ch4_BST_1
ch4_BST_0
ch4_Sel_scp
SMBus Register
0x2C[6]
0x2C[5]
0x2C[4]
0x2C[3]
0x2C[2]
0x2C[1]
0x2C[0]
0x2D[7]
0
1
0
1
1
1
1
1
Default
Value
0x10
0xAD
Default
Value
0x11
0x40
Default
Value
0x12
0x02
Default
Value
0x13
0xFA
Description
SMBus Register
Default
Value
0xD4
Default
Value
22
0x15
0x09
Default
Value
Default
Value
0x14
0x16
0x80
0x5F
0x17
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Register Maps (continued)
Table 7. EEPROM Register Map - Single Device with Default Value (continued)
EEPROM Address Byte
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
BIt 0
Description
ch4_Sel_mode
ch4_RES_2
ch4_RES_1
ch4_RES_0
ch4_VOD_2
ch4_VOD_1
ch4_VOD_0
ch4_DEM_2
SMBus Register
0x2D[6]
0x2D[5]
0x2D[4]
0x2D[3]
0x2D[2]
0x2D[1]
0x2D[0]
0x2E[2]
0
1
0
1
1
0
1
0
Description
ch4_DEM_1
ch4_DEM_0
ch4_Slow
ch4_idle_tha_1
ch4_idle_tha_0
ch4_idle_thd_1
ch4_idle_thd_0
ch5_Idle_auto
SMBus Register
0x2E[1]
0x2E[0]
0x2F[7]
0x2F[3]
0x2F[2]
0x2F[1]
0x2F[0]
0x32[5]
1
0
0
0
0
0
0
0
Description
ch5_Idle_sel
ch5_RXDET_1
ch5_RXDET_0
ch5_BST_7
ch5_BST_6
ch5_BST_5
ch5_BST_4
ch5_BST_3
SMBus Register
0x32[4]
0x32[3]
0x32[2]
0x33[7]
0x33[6]
0x33[5]
0x33[4]
0x33[3]
0
0
0
0
0
1
0
1
Description
ch5_BST_2
ch5_BST_1
ch5_BST_0
ch5_Sel_scp
ch5_Sel_mode
ch5_RES_2
ch5_RES_1
ch5_RES_0
SMBus Register
0x33[2]
0x33[1]
0x33[0]
0x34[7]
0x34[6]
0x34[5]
0x34[4]
0x34[3]
1
1
1
1
0
1
0
1
ch5_VOD_2
ch5_VOD_1
ch5_VOD_0
ch5_DEM_2
ch5_DEM_1
ch5_DEM_0
ch5_Slow
ch5_idle_tha_1
0x34[2]
0x34[1]
0x34[0]
0x35[2]
0x35[1]
0x35[0]
0x36[7]
0x36[3]
1
0
1
0
1
0
0
0
Description
ch5_idle_tha_0
ch5_idle_thd_1
ch5_idle_thd_0
ch6_Idle_auto
ch6_Idle_sel
ch6_RXDET_1
ch6_RXDET_0
ch6_BST_7
SMBus Register
0x36[2]
0x36[1]
0x36[0]
0x39[5]
0x39[4]
0x39[3]
0x39[2]
0x3A[7]
0
0
0
0
0
0
0
0
Description
ch6_BST_6
ch6_BST_5
ch6_BST_4
ch6_BST_3
ch6_BST_2
ch6_BST_1
ch6_BST_0
ch6_Sel_scp
SMBus Register
0x3A[6]
0x3A[5]
0x3A[4]
0x3A[3]
0x3A[2]
0x3A[1]
0x3A[0]
0x3B[7]
0
1
0
1
1
1
1
1
Description
ch6_Sel_mode
ch6_RES_2
ch6_RES_1
ch6_RES_0
ch6_VOD_2
ch6_VOD_1
ch6_VOD_0
ch6_DEM_2
SMBus Register
0x3B[6]
0x3B[5]
0x3B[4]
0x3B[3]
0x3B[2]
0x3B[1]
0x3B[0]
0x3C[2]
0
1
0
1
1
0
1
0
Default
Value
Default
Value
Default
Value
Default
Value
0x18
0x5A
0x19
0x80
0x1A
0x05
0x1B
0xF5
Description
SMBus Register
Default
Value
Default
Value
Default
Value
Default
Value
0x1C
0xA8
0x1D
0x00
0x1E
0x5F
0x5A
0x1F
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Register Maps (continued)
Table 7. EEPROM Register Map - Single Device with Default Value (continued)
EEPROM Address Byte
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
BIt 0
Description
ch6_DEM_1
ch6_DEM_0
ch6_Slow
ch6_idle_tha_1
ch6_idle_tha_0
ch6_idle_thd_1
ch6_idle_thd_0
ch7_Idle_auto
SMBus Register
0x3C[1]
0x3C[0]
0x3D[7]
0x3D[3]
0x3D[2]
0x3D[1]
0x3D[0]
0x40[5]
1
0
0
0
0
0
0
0
Description
ch7_Idle_sel
ch7_RXDET_1
ch7_RXDET_0
ch7_BST_7
ch7_BST_6
ch7_BST_5
ch7_BST_4
ch7_BST_3
SMBus Register
0x40[4]
0x40[3]
0x40[2]
0x41[7]
0x41[6]
0x41[5]
0x41[4]
0x41[3]
0
0
0
0
0
1
0
1
Description
ch7_BST_2
ch7_BST_1
ch7_BST_0
ch7_Sel_scp
ch7_Sel_mode
ch7_RES_2
ch7_RES_1
ch7_RES_0
SMBus Register
0x41[2]
0x41[1]
0x41[0]
0x42[7]
0x42[6]
0x42[5]
0x42[4]
0x42[3]
1
1
1
1
0
1
0
1
Description
ch7_VOD_2
ch7_VOD_1
ch7_VOD_0
ch7_DEM_2
ch7_DEM_1
ch7_DEM_0
ch7_Slow
ch7_idle_tha_1
SMBus Register
0x42[2]
0x42[1]
0x42[0]
0x43[2]
0x43[1]
0x43[0]
0x44[7]
0x44[3]
1
0
1
0
1
0
0
0
ch7_idle_tha_0
ch7_idle_thd_1
ch7_idle_thd_0
iph_dac_ns_1
iph_dac_ns_0
ipp_dac_ns_1
ipp_dac_ns_0
ipp_dac_1
0x44[2]
0x44[1]
0x44[0]
0x47[3]
0x47[2]
0x47[1]
0x47[0]
0x48[7]
0
0
0
0
0
0
0
0
Description
ipp_dac_0
RD23_67
RD01_45
RD_PD_ovrd
RD_Sel_test
RD_RESET_ovrd
PWDB_input_DC
DEM_VOD_ovrd
SMBus Register
0x48[6]
0x4C[7]
0x4C[6]
0x4C[5]
0x4C[4]
0x4C[3]
0x4C[0]
0x59[0]
0
0
0
0
0
0
0
0
Description
DEM_ovrd_N2
DEM_ovrd_N1
DEM_ovrd_N0
VOD_ovrd_N2
VOD_ovrd_N1
VOD_ovrd_N0
SPARE0
SPARE1
SMBus Register
0x5A[7]
0x5A[6]
0x5A[5]
0x5A[4]
0x5A[3]
0x5A[2]
0x5A[1]
0x5A[0]
0
1
0
1
0
1
0
0
Description
DEM__ovrd_S2
DEM__ovrd_S1
DEM_ovrd_S0
VOD_ovrd_S2
VOD_ovrd_S1
VOD_ovrd_S0
SPARE0
SPARE1
SMBus Register
0x5B[7]
0x5B[6]
0x5B[5]
0x5B[4]
0x5B[3]
0x5B[2]
0x5B[1]
0x5B[0]
0
1
0
1
0
1
0
0
Default
Value
0x20
0x80
Default
Value
0x21
0x05
Default
Value
0x22
0xF5
Default
Value
0x23
0xA8
Description
SMBus Register
Default
Value
0x00
Default
Value
24
0x25
0x00
Default
Value
Default
Value
0x24
0x26
0x54
0x54
0x27
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Table 8. Multi DS80PCI800 EEPROM Data (1)
EEPROM Address
Address (Hex)
EEPROM Data
Comments
0
00
0x43
CRC_EN = 0, Address Map = 1, >256 bytes = 0, Device
Count[3:0] = 3
1
01
0x00
2
02
0x10
EEPROM Burst Size
3
03
0x00
CRC not used
4
04
0x0B
Device 0 Address Location
5
05
0x00
CRC not used
6
06
0x0B
Device 1 Address Location
7
07
0x00
CRC not used
8
08
0x30
Device 2 Address Location
9
09
0x00
CRC not used
10
0A
0x30
Device 3 Address Location
11
0B
0x00
Begin Device 0, 1 - Address Offset 3
12
0C
0x00
13
0D
0x04
14
0E
0x07
15
0F
0x00
16
10
0x00
EQ CHB_0 = 0x00
17
11
0xAB
VOD CHB_0 = 1.0 V
18
12
0x00
DEM CHB_0 = 0 (0 dB)
19
13
0x00
EQ CHB_1 = 0x00
20
14
0x0A
VOD CHB_1 = 1.0 V
21
15
0xB0
DEM CHB_1 = 0 (0 dB)
22
16
0x00
23
17
0x00
EQ CHB_2 = 0x00
24
18
0xAB
VOD CHB_2 = 1.0 V
25
19
0x00
DEM CHB_2 = 0 (0 dB)
26
1A
0x00
EQ CHB_3 = 0x00
27
1B
0x0A
VOD CHB_3 = 1.0 V
28
1C
0xB0
DEM CHB_3 = 0 (0 dB)
29
1D
0x01
30
1E
0x80
31
1F
0x01
EQ CHA_0 = 0x00
32
20
0x56
VOD CHA_0 = 1.0 V
33
21
0x00
DEM CHA_0 = 0 (0 dB)
34
22
0x00
EQ CHA_1 = 0x00
35
23
0x15
VOD CHA_1 = 1.0 V
36
24
0x60
DEM CHA_1 = 0 (0 dB)
37
25
0x00
38
26
0x01
EQ CHA_2 = 0x00
39
27
0x56
VOD CHA_2 = 1.0 V
40
28
0x00
DEM CHA_2 = 0 (0 dB)
41
29
0x00
EQ CHA_3 = 0x00
42
2A
0x15
VOD CHA_3 = 1.0 V
43
2B
0x60
DEM CHA_3 = 0 (0 dB)
44
2C
0x00
(1)
CRC_EN = 0, Address Map = 1, >256 byte = 0, Device Count[3:0] = 3. This example has all 8 channels set to EQ = 0x00 (min boost),
VOD = 1.0 V, DEM = 0 (0 dB) and multiple device can point to the same address map.
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Table 8. Multi DS80PCI800 EEPROM Data(1) (continued)
EEPROM Address
Address (Hex)
EEPROM Data
45
2D
0x00
46
2E
0x54
47
2F
0x54
End Device 0, 1 - Address Offset 39
48
30
0x00
Begin Device 2, 3 - Address Offset 3
49
31
0x00
50
32
0x04
51
33
0x07
52
34
0x00
53
35
0x00
EQ CHB_0 = 0x00
54
36
0xAB
VOD CHB_0 = 1.0 V
55
37
0x00
DEM CHB_0 = 0 (0 dB)
56
38
0x00
EQ CHB_1 = 0x00
57
39
0x0A
VOD CHB_1 = 1.0 V
58
3A
0xB0
DEM CHB_1 = 0 (0 dB)
59
3B
0x00
60
3C
0x00
EQ CHB_2 = 0x00
61
3D
0xAB
VOD CHB_2 = 1.0 V
62
3E
0x00
DEM CHB_2 = 0 (0 dB)
63
3F
0x00
EQ CHB_3 = 0x00
64
40
0x0A
VOD CHB_3 = 1.0 V
65
41
0xB0
DEM CHB_3 = 0 (0 dB)
66
42
0x01
67
43
0x80
68
44
0x01
EQ CHA_0 = 0x00
69
45
0x56
VOD CHA_0 = 1.0 V
70
46
0x00
DEM CHA_0 = 0 (0 dB)
71
47
0x00
EQ CHA_1 = 0x00
72
48
0x15
VOD CHA_1 = 1.0 V
73
49
0x60
DEM CHA_1 = 0 (0 dB)
74
4A
0x00
75
4B
0x01
EQ CHA_2 = 0x00
76
4C
0x56
VOD CHA_2 = 1.0 V
77
4D
0x00
DEM CHA_2 = 0 (0 dB)
78
4E
0x00
EQ CHA_3 = 0x00
79
4F
0x15
VOD CHA_3 = 1.0 V
80
50
0x60
DEM CHA_3 = 0 (0 dB)
81
51
0x00
82
52
0x00
83
53
0x54
84
54
0x54
26
Comments
End Device 2, 3 - Address Offset 39
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Table 9. SMBus Slave Mode Register Map
Address Register Name
Bit
Field
Type
Default
0x00
7
Reserved
R/W
0x00
6:3
Address Bit
AD[3:0]
R
Observation of AD[3:0] bit
[6]: AD3
[5]: AD2
[4]: AD1
[3]: AD0
See Table 6
2
EEPROM Read
Done
R
1: Device completed the read from external
EEPROM
Device Address
Observation
1:0
Reserved
R/W
0x01
PWDN
Channels
7:0
PWDN CHx
R/W
0x00
0x02
Override
PRSNT Control
7
Override
RXDET
R/W
0x00
6
RXDET Value
5:2
Reserved
1
Reserved
0
Override
PRSNT
EEPROM
Bit
Description
Set bit to 0
Reserved
Yes
Power Down per Channel
[7]: CH7 – CHA_3
[6]: CH6 – CHA_2
[5]: CH5 – CHA_1
[4]: CH4 – CHA_0
[3]: CH3 – CHB_3
[2]: CH2 – CHB_2
[1]: CH1 – CHB_1
[0]: CH0 – CHB_0
0x00 = all channels enabled
0xFF = all channels disabled
Note: override PRSNT pin
1 = Override Automatic Rx Detect State
Machine Reset
1 = Set Rx Detect State Machine Reset
0 = Clear Rx Detect State Machine Reset
Yes
Set bits to 0
Set bit to 0
Yes
1: Block PRSNT pin control
0: Allow PRSNT pin control
0x03
Reserved
7:0
Reserved
R/W
0x00
0x04
Reserved
7:0
Reserved
R/W
0x00
0x05
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x06
Slave Register
Control
7:5
Reserved
R/W
0x10
Set bits to 0
4
Reserved
3
Register Enable
1 = Enables SMBus Slave Mode Register
Control
Note: To change VOD, DEM, and EQ of the
channels in slave mode, this bit must be set
to 1.
2:0
Reserved
Set bits to 0
7
Reserved
6
Reset Registers
Self clearing bit, set to 1 to reset the register to
default values.
5:0
Reserved
Set bits to 000001'b
0x07
Digital Reset
Control
Set bits to 0
Yes
Yes
R/W
0x01
Set bits to 0
Set bit to 1
Set bit to 0
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Table 9. SMBus Slave Mode Register Map (continued)
Address Register Name
Bit
Field
Type
Default
0x08
7
Reserved
R/W
0x00
6
Override
SD_TH
Yes
1: Block SD_TH pin control
0: Allow SD_TH pin control
5
Reserved
Yes
Set bit to 0
4
Override IDLE
Yes
1: IDLE control by registers
0: IDLE control by signal detect
3
Override
RXDET
Yes
1: Block RXDET pin control
0: Allow RXDET pin control
2
Override RATE
Yes
1: Block RATE pin control
0: Allow RATE pin control
Override
Pin Control
EEPROM
Bit
Description
Set bit to 0
1:0
Reserved
0x09
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x0A
Signal Detect
Monitor
7:0
SD_TH Status
R
0x00
CH7 - CH0 Internal Signal Detector Indicator
[7]: CH7 - CHA_3
[6]: CH6 - CHA_2
[5]: CH5 - CHA_1
[4]: CH4 - CHA_0
[3]: CH3 - CHB_3
[2]: CH2 - CHB_2
[1]: CH1 - CHB_1
[0]: CH0 - CHB_0
0 = Signal detected at input (active data)
1 = Signal not detected at input (idle state)
NOTE: These bits only function when RATE pin
= FLOAT.
0x0B
Reserved
7
Reserved
R/W
0x00
Set bits to 0
6:0
Reserved
R/W
0x70
0x0C
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x0D
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x0E
CH0 - CHB_0
IDLE, RXDET
7:6
Reserved
R/W
0x00
5
IDLE_AUTO
Yes
1 = Allow IDLE_SEL control in bit 4
0 = Automatic IDLE detect
Note: Override IDLE control
4
IDLE_SEL
Yes
1: Output is MUTED (electrical idle)
0: Output is ON
Note: Override IDLE control
3:2
RXDET
Yes
00: Input is hi-Z impedance
01: Auto RX-Detect,
outputs test every 12 ms for 600 ms (50 times)
then stops; termination is hi-Z until detection;
once detected input termination is 50 Ω
10: Auto RX-Detect,
outputs test every 12 ms until detection occurs;
termination is hi-Z until detection; once detected
input termination is 50 Ω
11: Input is 50 Ω
Note: Override RXDET pin
1:0
Reserved
7:0
EQ Control
0x0F
28
CH0 - CHB_0
EQ
Set bit to 0
Yes
Set bits to 111 0000'b
Set bits to 0
Set bits to 0
R/W
0x2F
Yes
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INB_0 EQ Control - total of 256 levels
See Table 2
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Table 9. SMBus Slave Mode Register Map (continued)
Address Register Name
Bit
Field
Type
Default
EEPROM
Bit
Description
0x10
7
Short Circuit
Protection
R/W
0xAD
Yes
1: Enable the short circuit protection
0: Disable the short circuit protection
6
RATE_SEL
Yes
1: Gen 1/2
0: Gen 3
Note: Override the RATE pin
5:3
Reserved
Yes
Set bits to default value - 101
2:0
VOD Control
Yes
OUTB_0 VOD Control
000: 0.7 V
001: 0.8 V
010: 0.9 V
011: 1.0 V
100: 1.1 V
101: 1.2 V (default)
110: 1.3 V
111: 1.4 V
7
RXDET
STATUS
R
6:5
RATE_DET
STATUS
R
4:3
Reserved
R/W
2:0
DEM Control
R/W
7
Reserved
R/W
6:4
Reserved
3:2
IDLE tha
Yes
Assert threshold
00 = 180 mVp-p (default)
01 = 160 mVp-p
10 = 210 mVp-p
11 = 190 mVp-p
Note: Override the SD_TH pin
1:0
IDLE thd
Yes
Deassert threshold
00 = 110 mVp-p (default)
01 = 100 mVp-p
10 = 150 mVp-p
11 = 130 mVp-p
Note: Override the SD_TH pin
0x11
0x12
CH0 - CHB_0
VOD
CH0 - CHB_0
DEM
CH0 - CHB_0
IDLE Threshold
0x02
Observation bit for RXDET CH0 - CHB_0
1: RX = detected
0: RX = not detected
Observation bit for RATE_DET CH0 - CHB_0
00: GEN1 (2.5G)
01: GEN2 (5G)
11: GEN3 (8G)
Set bits to 0
0x00
Yes
OUTB_0 DEM Control
000: 0 dB
001: –1.5 dB
010: –3.5 dB (default)
011: –5 dB
100: –6 dB
101: –8 dB
110: –9 dB
111: –12 dB
Yes
Set bit to 0
Set bits to 0
0x13
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x14
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
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Table 9. SMBus Slave Mode Register Map (continued)
Address Register Name
Bit
Field
Type
Default
0x15
7:6
Reserved
R/W
0x00
5
IDLE_AUTO
Yes
1 = Allow IDLE_SEL control in bit 4
0 = Automatic IDLE detect
Note: Override IDLE control
4
IDLE_SEL
Yes
1: Output is MUTED (electrical idle)
0: Output is ON
Note: Override IDLE control
3:2
RXDET
Yes
00: Input is hi-Z impedance
01: Auto RX-Detect,
outputs test every 12 ms for 600 ms (50 times)
then stops; termination is hi-Z until detection;
once detected input termination is 50 Ω
10: Auto RX-Detect,
outputs test every 12 ms until detection occurs;
termination is hi-Z until detection; once detected
input termination is 50 Ω
11: Input is 50 Ω
Note: Override RXDET pin
1:0
Reserved
CH1 - CHB_1
IDLE, RXDET
EEPROM
Bit
Description
Set bits to 0
Set bits to 0.
0x16
CH1 - CHB_1
EQ
7:0
EQ Control
R/W
0x2F
Yes
INB_1 EQ Control - total of 256 levels.
See Table 2
0x17
CH1 - CHB_1
VOD
7
Short Circuit
Protection
R/W
0xAD
Yes
1: Enable the short circuit protection
0: Disable the short circuit protection
6
RATE_SEL
Yes
1: Gen 1/2
0: Gen 3
Note: Override the RATE pin
5:3
Reserved
Yes
Set bits to default value - 101
2:0
VOD Control
Yes
OUTB_1 VOD Control
000: 0.7 V
001: 0.8 V
010: 0.9 V
011: 1.0 V
100: 1.1 V
101: 1.2 V (default)
110: 1.3 V
111: 1.4 V
7
RXDET
STATUS
R
6:5
RATE_DET
STATUS
R
4:3
Reserved
R/W
2:0
DEM Control
R/W
0x18
30
CH1 - CHB_1
DEM
0x02
Observation bit for RXDET CH1 - CHB_1
1: RX = detected
0: RX = not detected
Observation bit for RATE_DET CH1 - CHB_1
00: GEN1 (2.5G)
01: GEN2 (5G)
11: GEN3 (8G)
Set bits to 0
Yes
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OUTB_1 DEM Control
000: 0 dB
001: –1.5 dB
010: –3.5 dB (default)
011: –5 dB
100: –6 dB
101: –8 dB
110: –9 dB
111: –12 dB
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Table 9. SMBus Slave Mode Register Map (continued)
Address Register Name
Bit
Field
Type
Default
EEPROM
Bit
Description
0x19
7
Reserved
R/W
0x00
Yes
Set bit to 0.
6:4
Reserved
3:2
IDLE tha
Yes
Assert threshold
00 = 180 mVp-p (default)
01 = 160 mVp-p
10 = 210 mVp-p
11 = 190 mVp-p
Note: Override the SD_TH pin
1:0
IDLE thd
Yes
Deassert threshold
00 = 110 mVp-p (default)
01 = 100 mVp-p
10 = 150 mVp-p
11 = 130 mVp-p
Note: Override the SD_TH pin
CH1 - CHB_1
IDLE Threshold
Set bits to 0.
0x1A
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x1B
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x1C
CH2 - CHB_2
IDLE, RXDET
7:6
Reserved
R/W
0x00
5
IDLE_AUTO
Yes
1 = Allow IDLE_SEL control in bit 4
0 = Automatic IDLE detect
Note: Override IDLE control
4
IDLE_SEL
Yes
1: Output is MUTED (electrical idle)
0: Output is ON
Note: Override IDLE control
3:2
RXDET
Yes
00: Input is hi-Z impedance
01: Auto RX-Detect,
outputs test every 12 ms for 600 ms (50 times)
then stops; termination is hi-Z until detection;
once detected input termination is 50 Ω
10: Auto RX-Detect,
outputs test every 12 ms until detection occurs;
termination is hi-Z until detection; once detected
input termination is 50 Ω
11: Input is 50 Ω
Note: Override RXDET pin
Set bits to 0
1:0
Reserved
0x1D
CH2 - CHB_2
EQ
7:0
EQ Control
R/W
0x2F
Yes
Set bits to 0
INB_2 EQ Control - total of 256 levels.
See Table 2
0x1E
CH2 - CHB_2
VOD
7
Short Circuit
Protection
R/W
0xAD
Yes
1: Enable the short circuit protection
0: Disable the short circuit protection
6
RATE_SEL
Yes
1: Gen 1/2
0: Gen 3
Note: Override the RATE pin
5:3
Reserved
Yes
Set bits to default value - 101
2:0
VOD Control
Yes
OUTB_2 VOD Control
000: 0.7 V
001: 0.8 V
010: 0.9 V
011: 1.0 V
100: 1.1 V
101: 1.2 V (default)
110: 1.3 V
111: 1.4 V
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Table 9. SMBus Slave Mode Register Map (continued)
Address Register Name
Bit
Field
Type
Default
0x1F
7
RXDET
STATUS
R
0x02
6:5
RATE_DET
STATUS
R
4:3
Reserved
R/W
2:0
DEM Control
R/W
7
Reserved
R/W
6:4
Reserved
3:2
IDLE tha
Yes
Assert threshold
00 = 180 mVp-p (default)
01 = 160 mVp-p
10 = 210 mVp-p
11 = 190 mVp-p
Note: Override the SD_TH pin.Set bits to 0
1:0
IDLE thd
Yes
Deassert threshold
00 = 110 mVp-p (default)
01 = 100 mVp-p
10 = 150 mVp-p
11 = 130 mVp-p
Note: Override the SD_TH pin
0x20
CH2 - CHB_2
DEM
CH2 - CHB_2
IDLE Threshold
EEPROM
Bit
Description
Observation bit for RXDET CH2 - CHB_2
1: RX = detected
0: RX = not detected
Observation bit for RATE_DET CH2 - CHB_2
00: GEN1 (2.5G)
01: GEN2 (5G)
11: GEN3 (8G)
Set bits to 0.
0x00
Yes
OUTB_2 DEM Control
000: 0 dB
001: –1.5 dB
010: –3.5 dB (default)
011: –5 dB
100: –6 dB
101: –8 dB
110: –9 dB
111: –12 dB
Yes
Set bit to 0
Set bits to 0
0x21
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x22
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x23
CH3 - CHB_3
IDLE, RXDET
7:6
Reserved
R/W
0x00
Set bits to 0
5
IDLE_AUTO
Yes
1 = Allow IDLE_SEL control in bit 4
0 = Automatic IDLE detect
Note: Override IDLE control
4
IDLE_SEL
Yes
1: Output is MUTED (electrical idle)
0: Output is ON
Note: Override IDLE control.
3:2
RXDET
Yes
00: Input is hi-Z impedance
01: Auto RX-Detect,
outputs test every 12 ms for 600 ms (50 times)
then stops; termination is hi-Z until detection;
once detected input termination is 50 Ω
10: Auto RX-Detect,
outputs test every 12 ms until detection occurs;
termination is hi-Z until detection; once detected
input termination is 50 Ω
11: Input is 50 Ω
Note: Override RXDET pin
1:0
Reserved
7:0
EQ Control
0x24
32
CH3 - CHB_3
EQ
Set bits to 0
R/W
0x2F
Yes
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INB_3 EQ Control - total of 256 levels.
See Table 2
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Table 9. SMBus Slave Mode Register Map (continued)
Address Register Name
Bit
Field
Type
Default
EEPROM
Bit
Description
0x25
7
Short Circuit
Protection
R/W
0xAD
Yes
1: Enable the short circuit protection
0: Disable the short circuit protection
6
RATE_SEL
Yes
1: Gen 1/2
0: Gen 3
Note: Override the RATE pin
5:3
Reserved
Yes
Set bits to default value - 101
2:0
VOD Control
Yes
OUTB_3 VOD Control
000: 0.7 V
001: 0.8 V
010: 0.9 V
011: 1.0 V
100: 1.1 V
101: 1.2 V (default)
110: 1.3 V
111: 1.4 V
7
RXDET
STATUS
R
6:5
RATE_DET
STATUS
R
4:3
Reserved
R/W
2:0
DEM Control
R/W
7
Reserved
R/W
6:4
Reserved
3:2
IDLE tha
Yes
Assert threshold
00 = 180 mVp-p (default)
01 = 160 mVp-p
10 = 210 mVp-p
11 = 190 mVp-p
Note: Override the SD_TH pin
1:0
IDLE thd
Yes
Deassert threshold
00 = 110 mVp-p (default)
01 = 100 mVp-p
10 = 150 mVp-p
11 = 130 mVp-p
Note: Override the SD_TH pin
7
Reserved
6
Reserved
Yes
Set bit to 0
5:4
High SD_TH
Status
Yes
Enable Higher Range of Signal Detect Status
Thresholds
[5]: CH0 - CH3
[4]: CH4 - CH7
3:2
Fast Signal
Detect Status
Yes
Enable Fast Signal Detect Status
[3]: CH0 - CH3
[2]: CH4 - CH7
Note: In Fast Signal Detect, assert/deassert
response occurs after approximately 3-4 ns
1:0
Reduced SD
Status Gain
Yes
Enable Reduced Signal Detect Status Gain
[1]: CH0 - CH3
[0]: CH4 - CH7
0x26
0x27
0x28
CH3 - CHB_3
VOD
CH3 - CHB_3
DEM
CH3 - CHB_3
IDLE Threshold
Signal Detect
Status Control
0x02
Observation bit for RXDET CH3 - CHB_3
1: RX = detected
0: RX = not detected
Observation bit for RATE_DET CH3 - CHB_3
00: GEN1 (2.5G)
01: GEN2 (5G)
11: GEN3 (8G)
Set bits to 0
0x00
Yes
OUTB_3 DEM Control
000: 0 dB
001: –1.5 dB
010: –3.5 dB (default)
011: –5 dB
100: –6 dB
101: –8 dB
110: –9 dB
111: –12 dB
Yes
Set bit to 0
Set bits to 0
R/W
0x0C
Set bit to 0
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Table 9. SMBus Slave Mode Register Map (continued)
Address Register Name
Bit
Field
Type
Default
EEPROM
Bit
Description
0x29
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x2A
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x2B
CH4 - CHA_0
IDLE, RXDET
7:6
Reserved
R/W
0x00
Set bits to 0
5
IDLE_AUTO
Yes
1 = Allow IDLE_SEL control in bit 4
0 = Automatic IDLE detect
Note: Override IDLE control
4
IDLE_SEL
Yes
1: Output is MUTED (electrical idle)
0: Output is ON
Note: Override IDLE control
3:2
RXDET
Yes
00: Input is hi-Z impedance
01: Auto RX-Detect,
outputs test every 12 ms for 600 ms (50 times)
then stops; termination is hi-Z until detection;
once detected input termination is 50 Ω
10: Auto RX-Detect,
outputs test every 12 ms until detection occurs;
termination is hi-Z until detection; once detected
input termination is 50 Ω
11: Input is 50 Ω
Note: Override RXDET pin
1:0
Reserved
0x2C
CH4 - CHA_0
EQ
7:0
EQ Control
R/W
0x2F
Yes
INA_0 EQ Control - total of 256 levels
See Table 2
0x2D
CH4 - CHA_0
VOD
7
Short Circuit
Protection
R/W
0xAD
Yes
1: Enable the short circuit protection
0: Disable the short circuit protection
6
RATE_SEL
Yes
1: Gen 1/2
0: Gen 3
Note: Override the RATE pin
5:3
Reserved
Yes
Set bits to default value - 101
2:0
VOD Control
Yes
OUTA_0 VOD Control
000: 0.7 V
001: 0.8 V
010: 0.9 V
011: 1.0 V
100: 1.1 V
101: 1.2 V (default)
110: 1.3 V
111: 1.4 V
7
RXDET
STATUS
R
6:5
RATE_DET
STATUS
R
4:3
Reserved
R/W
2:0
DEM Control
R/W
0x2E
34
CH4 - CHA_0
DEM
Set bits to 0
0x02
Observation bit for RXDET CH4 - CHA_0
1: RX = detected
0: RX = not detected
Observation bit for RATE_DET CH4 - CHA_0
00: GEN1 (2.5G)
01: GEN2 (5G)
11: GEN3 (8G)
Set bits to 0
Yes
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OUTA_0 DEM Control
000: 0 dB
001: –1.5 dB
010: –3.5 dB (default)
011: –5 dB
100: –6 dB
101: –8 dB
110: –9 dB
111: –12 dB
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Table 9. SMBus Slave Mode Register Map (continued)
Address Register Name
Bit
Field
Type
Default
EEPROM
Bit
Description
0x2F
7
Reserved
R/W
0x00
Yes
Set bit to 0
6:4
Reserved
3:2
IDLE tha
Yes
Assert threshold
00 = 180 mVp-p (default)
01 = 160 mVp-p
10 = 210 mVp-p
11 = 190 mVp-p
Note: Override the SD_TH pin
1:0
IDLE thd
Yes
Deassert threshold
00 = 110 mVp-p (default)
01 = 100 mVp-p
10 = 150 mVp-p
11 = 130 mVp-p
Note: Override the SD_TH pin
CH4 - CHA_0
IDLE Threshold
Set bits to 0
0x30
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x31
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x32
CH5 - CHA_1
IDLE, RXDET
7:6
Reserved
R/W
0x00
5
IDLE_AUTO
Yes
1 = Allow IDLE_SEL control in bit 4
0 = Automatic IDLE detect
Note: Override IDLE control
4
IDLE_SEL
Yes
1: Output is MUTED (electrical idle)
0: Output is ON
Note: Override IDLE control
3:2
RXDET
Yes
00: Input is hi-Z impedance
01: Auto RX-Detect,
outputs test every 12 ms for 600 ms (50 times)
then stops; termination is hi-Z until detection;
once detected input termination is 50 Ω
10: Auto RX-Detect,
outputs test every 12 ms until detection occurs;
termination is hi-Z until detection; once detected
input termination is 50 Ω
11: Input is 50 Ω
Note: override RXDET pin
Set bits to 0
1:0
Reserved
0x33
CH5 - CHA_1
EQ
7:0
EQ Control
R/W
0x2F
Yes
Set bits to 0
INA_1 EQ Control - total of 256 levels
See Table 2
0x34
CH5 - CHA_1
VOD
7
Short Circuit
Protection
R/W
0xAD
Yes
1: Enable the short circuit protection
0: Disable the short circuit protection
6
RATE_SEL
Yes
1: Gen 1/2
0: Gen 3
Note: Override the RATE pin
5:3
Reserved
Yes
Set bits to default value - 101
2:0
VOD Control
Yes
OUTA_1 VOD Control
000: 0.7 V
001: 0.8 V
010: 0.9 V
011: 1.0 V
100: 1.1 V
101: 1.2 V (default)
110: 1.3 V
111: 1.4 V
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Table 9. SMBus Slave Mode Register Map (continued)
Address Register Name
Bit
Field
Type
Default
0x35
7
RXDET
STATUS
R
0x02
6:5
RATE_DET
STATUS
R
4:3
Reserved
R/W
2:0
DEM Control
R/W
7
Reserved
R/W
6:4
Reserved
3:2
IDLE tha
Yes
Assert threshold
00 = 180 mVp-p (default)
01 = 160 mVp-p
10 = 210 mVp-p
11 = 190 mVp-p
Note: Override the SD_TH pin
1:0
IDLE thd
Yes
Deassert threshold
00 = 110 mVp-p (default)
01 = 100 mVp-p
10 = 150 mVp-p
11 = 130 mVp-p
Note: Override the SD_TH pin
0x36
CH5 - CHA_1
DEM
CH5 - CHA_1
IDLE Threshold
EEPROM
Bit
Description
Observation bit for RXDET CH5 - CHA_1
1: RX = detected
0: RX = not detected
Observation bit for RATE_DET CH5 - CHA_1
00: GEN1 (2.5G)
01: GEN2 (5G)
11: GEN3 (8G)
Set bits to 0
0x00
Yes
OUTA_1 DEM Control
000: 0 dB
001: –1.5 dB
010: –3.5 dB (default)
011: –5 dB
100: –6 dB
101: –8 dB
110: –9 dB
111: –12 dB
Yes
Set bit to 0
Set bits to 0
0x37
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x38
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x39
CH6 - CHA_2
IDLE, RXDET
7:6
Reserved
R/W
0x00
Set bits to 0
5
IDLE_AUTO
Yes
1 = Allow IDLE_SEL control in bit 4
0 = Automatic IDLE detect
Note: Override IDLE control
4
IDLE_SEL
Yes
1: Output is MUTED (electrical idle)
0: Output is ON
Note: Override IDLE control
3:2
RXDET
Yes
00: Input is hi-Z impedance
01: Auto RX-Detect,
outputs test every 12 ms for 600 ms (50 times)
then stops; termination is hi-Z until detection;
once detected input termination is 50 Ω
10: Auto RX-Detect,
outputs test every 12 ms until detection occurs;
termination is hi-Z until detection; once detected
input termination is 50 Ω
11: Input is 50 Ω
Note: Override RXDET pin
1:0
Reserved
7:0
EQ Control
0x3A
36
CH6 - CHA_2
EQ
Set bits to 0
R/W
0x2F
Yes
Submit Documentation Feedback
INA_2 EQ Control - total of 256 levels
See Table 2
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Table 9. SMBus Slave Mode Register Map (continued)
Address Register Name
Bit
Field
Type
Default
EEPROM
Bit
Description
0x3B
7
Short Circuit
Protection
R/W
0xAD
Yes
1: Enable the short circuit protection
0: Disable the short circuit protection
6
RATE_SEL
Yes
1: Gen 1/2
0: Gen 3
Note: Override the RATE pin
5:3
Reserved
Yes
Set bits to default value - 101
2:0
VOD Control
Yes
OUTA_2 VOD Control
000: 0.7 V
001: 0.8 V
010: 0.9 V
011: 1.0 V
100: 1.1 V
101: 1.2 V (default)
110: 1.3 V
111: 1.4 V
7
RXDET
STATUS
R
6:5
RATE_DET
STATUS
R
4:3
Reserved
R/W
2:0
DEM Control
R/W
7
Reserved
R/W
6:4
Reserved
3:2
IDLE tha
Yes
Assert threshold
00 = 180 mVp-p (default)
01 = 160 mVp-p
10 = 210 mVp-p
11 = 190 mVp-p
Note: Override the SD_TH pin
1:0
IDLE thd
Yes
Deassert threshold
00 = 110 mVp-p (default)
01 = 100 mVp-p
10 = 150 mVp-p
11 = 130 mVp-p
Note: Override the SD_TH pin
0x3C
0x3D
CH6 - CHA_2
VOD
CH6 - CHA_2
DEM
CH6 - CHA_2
IDLE Threshold
0x02
Observation bit for RXDET CH6 - CHA_2
1: RX = detected
0: RX = not detected
Observation bit for RATE_DET CH6 - CHA_2
00: GEN1 (2.5G)
01: GEN2 (5G)
11: GEN3 (8G)
Set bits to 0
0x00
Yes
OUTA_2 DEM Control
000: 0 dB
001: –1.5 dB
010: –3.5 dB (default)
011: –5 dB
100: –6 dB
101: –8 dB
110: –9 dB
111: –12 dB
Yes
Set bit to 0
Set bits to 0
0x3E
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x3F
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
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Table 9. SMBus Slave Mode Register Map (continued)
Address Register Name
Bit
Field
Type
Default
0x40
7:6
Reserved
R/W
0x00
5
IDLE_AUTO
Yes
1 = Allow IDLE_SEL control in bit 4
0 = Automatic IDLE detect
Note: Override IDLE control
4
IDLE_SEL
Yes
1: Output is MUTED (electrical idle)
0: Output is ON
Note: Override IDLE control
3:2
RXDET
Yes
00: Input is hi-Z impedance
01: Auto RX-Detect,
outputs test every 12 ms for 600 ms (50 times)
then stops; termination is hi-Z until detection;
once detected input termination is 50 Ω
10: Auto RX-Detect,
outputs test every 12 ms until detection occurs;
termination is hi-Z until detection; once detected
input termination is 50 Ω
11: Input is 50 Ω
Note: Override RXDET pin
1:0
Reserved
CH7 - CHA_3
IDLE, RXDET
EEPROM
Bit
Description
Set bits to 0
Set bits to 0
0x41
CH7 - CHA_3
EQ
7:0
EQ Control
R/W
0x2F
Yes
INA_3 EQ Control - total of 256 levels
See Table 2
0x42
CH7 - CHA_3
VOD
7
Short Circuit
Protection
R/W
0xAD
Yes
1: Enable the short circuit protection
0: Disable the short circuit protection
6
RATE_SEL
Yes
1: Gen 1/2
0: Gen 3
Note: Override the RATE pin
5:3
Reserved
Yes
Set bits to default value - 101
2:0
VOD Control
Yes
OUTA_3 VOD Control
000: 0.7 V
001: 0.8 V
010: 0.9 V
011: 1.0 V
100: 1.1 V
101: 1.2 V (default)
110: 1.3 V
111: 1.4 V
7
RXDET
STATUS
R
6:5
RATE_DET
STATUS
R
4:3
Reserved
R/W
2:0
DEM Control
R/W
0x43
38
CH7 - CHA_3
DEM
0x02
Observation bit for RXDET CH7 - CHA_3
1: RX = detected
0: RX = not detected
Observation bit for RATE_DET CH7 - CHA_3
00: GEN1 (2.5G)
01: GEN2 (5G)
11: GEN3 (8G)
Set bits to 0
Yes
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OUTA_3 DEM Control
000: 0 dB
001: –1.5 dB
010: –3.5 dB (default)
011: –5 dB
100: –6 dB
101: –8 dB
110: –9 dB
111: –12 dB
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Table 9. SMBus Slave Mode Register Map (continued)
Address Register Name
Bit
Field
Type
Default
EEPROM
Bit
Description
0x44
7
Reserved
R/W
0x00
Yes
Set bit to 0
6:4
Reserved
3:2
IDLE tha
Yes
Assert threshold
00 = 180 mVp-p (default)
01 = 160 mVp-p
10 = 210 mVp-p
11 = 190 mVp-p
Note: Override the SD_TH pin
1:0
IDLE thd
Yes
Deassert threshold
00 = 110 mVp-p (default)
01 = 100 mVp-p
10 = 150 mVp-p
11 = 130 mVp-p
Note: Override the SD_TH pin
CH7 - CHA_3
IDLE Threshold
Set bits to 0
0x45
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x46
Reserved
7:0
Reserved
R/W
0x38
Set bits to 0x38
0x47
Reserved
7:4
Reserved
R/W
0x00
3:0
Reserved
R/W
7:6
Reserved
R/W
5:0
Reserved
R/W
0x48
Reserved
0x05
Set bits to 0
Yes
Set bits to 0
Yes
Set bits to 0
Set bits to 00 0101'b
0x49
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x4A
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x4B
Reserved
7:0
Reserved
R/W
0x00
0x4C
Reserved
7:3
Reserved
R/W
0x00
2:1
Reserved
R/W
Set bits to 0
Yes
Set bits to 0
Set bits to 0
0
Reserved
R/W
0x4D
Reserved
7:0
Reserved
R/W
0x00
Yes
Set bits to 0
Set bits to 0
0x4E
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x4F
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x50
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x51
Device ID
7:5
VERSION
R
0x45
010'b
4:0
ID
0x52
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x53
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x54
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x55
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x56
Reserved
7:0
Reserved
R/W
0x10
Set bits to 0x10
0x57
Reserved
7:0
Reserved
R/W
0x64
Set bits to 0x64
0x58
Reserved
7:0
Reserved
R/W
0x21
Set bits to 0x21
0x59
Reserved
7:1
Reserved
R/W
0x00
0
Reserved
00101'b
Set bits to 0
Yes
Set bit to 0
0x5A
Reserved
7:0
Reserved
R/W
0x54
Yes
Set bits to 0x54
0x5B
Reserved
7:0
Reserved
R/W
0x54
Yes
Set bits to 0x54
0x5C
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x5D
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x5E
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x5F
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x60
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
0x61
Reserved
7:0
Reserved
R/W
0x00
Set bits to 0
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9 Application and Implementation
NOTE
Information in the following applications sections is not part of the TI component
specification, and TI does not warrant its accuracy or completeness. TI’s customers are
responsible for determining suitability of components for their purposes. Customers should
validate and test their design implementation to confirm system functionality.
9.1 Application Information
9.1.1 DS80PCI800 versus DS80PCI810
The DS80PCI800 and DS80PCI810 are pin compatible, and both can be used for PCIe Gen-1, 2, and 3
applications. The DS80PCI800 is ideal for closed PCIe systems where significant insertion losses (> 35 dB at 4
GHz) are expected in the signal path. A closed system is defined as a PCIe environment with a limited number of
possible Host-to-Endpoint combinations. The DS80PCI800 can extend the reach of a PCIe system by up to 36
dB beyond the max allowable PCIe channel loss, whereas the DS80PCI810 can extend the system range up to
10 dB while offering a larger dynamic range on output linearity. Due to the larger CTLE gain, the DS80PCI800 is
able to compensate insertion loss over longer transmission lines before the repeater. In addition, the
DS80PCI800 is able to produce de-emphasis levels up to -12 dB to support significant trace losses after the
repeater (-15 dB at 4 GHz).
9.1.2 Signal Integrity in PCIe Applications
In PCIe Gen-3 applications, the specification requires Rx-Tx link training to establish and optimize signal
conditioning settings at 8 Gbps. In link training, the Rx partner requests a series of FIR - preshoot and deemphasis coefficients (10 Presets) from the Tx partner. The Rx partner includes 7-levels (6 dB to 12 dB) of CTLE
followed by a single tap DFE. The link training would pre-condition the signal with an equalized link between the
root-complex and endpoint. Note that there is no link training in PCIe Gen-1 (2.5 Gbps) or PCIe Gen-2 (5.0
Gbps) applications. The DS80PCI800 is placed in between the Tx and Rx. It would help extend the PCB trace
reach distance by boosting the attenuated signals with it's equalization, so that the signal can be more easily
recovered by the downstream Rx. In Gen 3 mode, DS80PCI800 transmit outputs are designed to pass the Tx
Preset signaling onto the Rx for the PCIe Gen 3 link to train and optimize the equalization settings. The
suggested setting for the DS80PCI800 are EQ = 0x00, VOD = 1.2 Vp-p and DEM = 0 dB. Additional adjustments
to increase the EQ or DEM setting should be performed to optimize the eye opening in the Rx partner. See the
tables below for Pin Mode and SMBus Mode configurations.
Table 10. Suggested Device Settings in Pin Mode
Channel
Pin Mode Settings
EQx[1:0]
0, 0 (Level 1)
DEMx[1:0]
Float, R (Level 10)
Table 11. Suggested Device Settings in SMBus Slave Mode
40
Register
Write Value
0x06
0x18
Comments
Enables SMBus Slave Mode Register Control
0x0F
0x00
Set CHB_0 EQ to 0x00.
0x10
0xAD
Set CHB_0 VOD to 101'b (1.2 Vp-p).
0x11
0x00
Set CHB_0 DEM to 000'b (0 dB).
0x16
0x00
Set CHB_1 EQ to 0x00.
0x17
0xAD
Set CHB_1 VOD to 101'b (1.2 Vp-p).
0x18
0x00
Set CHB_1 DEM to 000'b (0 dB).
0x1D
0x00
Set CHB_2 EQ to 0x00.
0x1E
0xAD
Set CHB_2 VOD to 101'b (1.2 Vp-p).
0x1F
0x00
Set CHB_2 DEM to 000'b (0 dB).
0x24
0x00
Set CHB_3 EQ to 0x00.
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Table 11. Suggested Device Settings in SMBus Slave Mode (continued)
Register
Write Value
0x25
0xAD
Comments
Set CHB_3 VOD to 101'b (1.2 Vp-p).
0x26
0x00
Set CHB_3 DEM to 000'b (0 dB).
0x2C
0x00
Set CHA_0 EQ to 0x00.
0x2D
0xAD
Set CHA_0 VOD to 101'b (1.2 Vp-p).
0x2E
0x00
Set CHA_0 DEM to 000'b (0 dB).
0x33
0x00
Set CHA_1 EQ to 0x00.
0x34
0xAD
Set CHA_1 VOD to 101'b (1.2 Vp-p).
0x35
0x00
Set CHA_1 DEM to 000'b (0 dB).
0x3A
0x00
Set CHA_2 EQ to 0x00.
0x3B
0xAD
Set CHA_2 VOD to 101'b (1.2 Vp-p).
0x3C
0x00
Set CHA_2 DEM to 000'b (0 dB).
0x41
0x00
Set CHA_3 EQ to 0x00.
0x42
0xAD
Set CHA_3 VOD to 101'b (1.2 Vp-p).
0x43
0x00
Set CHA_3 DEM to 000'b (0 dB).
9.2 Typical Application
The DS80PCI800 extends PCB trace and cable reach in PCIe Gen1, 2 and 3 applications by applying
equalization to compensate for the insertion loss of the trace or cable. In Gen 3 mode, the device aids
specifically in the equalization link training to improve the margin and overall eye inside the Rx. The DS80PCI800
can be used on the motherboard, mid plane (riser card), end-point target cards, and active cable assemblies.
The capability of the DS80PCI800 performance is shown in the following two test setup connections.
Pattern
Generator
VID = 1.0 Vp-p,
DE = 0 dB
8 Gb/s, PRBS23
TL
Lossy Channel
IN
DS80PCI800
OUT
Scope
BW = 50 GHz
Figure 8. Test Setup 1 Connections Diagram
Pattern
Generator
VID = 1.0 Vp-p,
DE = -9 dB
8 Gb/s, PRBS23
TL1
Lossy Channel
IN
DS80PCI800
OUT
Scope
BW = 50 GHz
TL2
Lossy Channel
Figure 9. Test Setup 2 Connections Diagram
9.2.1 Design Requirements
As with any high speed design, there are many factors which influence the overall performance. The following list
indicates critical areas for consideration during design.
• Use 100 Ω impedance traces. Length matching on the P and N traces should be done on the single-end
segments of the differential pair.
• Use uniform trace width and trace spacing for differential pairs.
• Place AC-coupling capacitors near to the receiver end of each channel segment to minimize reflections.
• For Gen3, AC-coupling capacitors of 220 nF are recommended, maximum body size is 0402, and add cutout
void on GND plane below the landing pad of the capacitor to reduce parasitic capacitance to GND.
• Back-drill connector vias and signal vias to minimize stub length.
• Use Reference plane vias to ensure a low inductance path for the return current.
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Typical Application (continued)
9.2.2 Detailed Design Procedure
The DS80PCI800 should be placed at an offset location and close to the Rx with respect to the overall channel
attenuation. The suggested settings are recommended as a starting point for most applications. Once these
settings are configured, additional adjustments of the DS80PCI800 EQ or DE may be required to optimize the
repeater performance. The CTLE and DFE coefficient in the Rx can also be adjusted to further improve the eye
opening.
9.2.3 Application Curves
DS80PCI800 Settings:
EQ[1:0] = [R, R] or 0x15, DEM[1:0] = [Float, Float]
Figure 10. Test Setup 1, TL = 20-Inch 4-Mil FR4 Trace
DS80PCI800 Settings:
EQ[1:0] = [Float, R] or 0x1F, DEM[1:0] = [Float, Float]
Figure 11. Test Setup 1, TL = 35-Inch 4-Mil FR4 Trace
DS80PCI800 Settings:
EQ[1:0] = [R, R] or 0x15, DEM[1:0] = [Float, Float]
Figure 12. Test Setup 2, TL1 = 20-Inch 4-Mil FR4 Trace,
TL2 = 15-Inch 4-Mil FR4 Trace
DS80PCI800 Settings:
EQ[1:0] = [R, 1] or 0x0F, DEM[1:0] = [Float, Float]
Figure 13. Test Setup 2, TL1 = 30-Inch 4-Mil FR4 Trace,
TL2 = 15-Inch 4-Mil FR4 Trace
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10 Power Supply Recommendations
10.1 3.3-V or 2.5-V Supply Mode Operation
The DS80PCI800 has an optional internal voltage regulator to provide the 2.5 V supply to the device. In 3.3-V
mode, the VIN pin = 3.3 V is used to supply power to the device and the VDD pins should be left open. The
internal regulator will provide the 2.5 V to the VDD pins of the device and a 0.1 μF cap is needed at each of the
five VDD pins for power supply de-coupling (total capacitance should be ≤ 0.5 µF), and the VDD pins should be
left open. The VDD_SEL pin must be tied to GND to enable the internal regulator. In 2.5-V mode, the VIN pin
should be left open and 2.5 V supply must be applied to the VDD pins. The VDD_SEL pin must be left open (no
connect) to disable the internal regulator.
The DS80PCI800 can be configured for 2.5 V operation or 3.3 V operation. The lists below outline required
connections for each supply selection.
3.3-V Mode of Operation
1. Tie VDD_SEL = 0 with 1-kΩ resistor to GND.
2. Feed 3.3-V supply into VIN pin. Local 1.0-µF decoupling at VIN is recommended.
3. See information on VDD bypass below.
4. SDA and SCL pins should connect pullup resistor to VIN
5. Any 4-Level input which requires a connection to "Logic 1" should use a 1-kΩ resistor to VIN
2.5-V Mode of Operation
1. VDD_SEL = Float
2. VIN = Float
3. Feed 2.5-V supply into VDD pins.
4. See information on VDD bypass below.
5. SDA and SCL pins connect pullup resistor to VDD for 2.5-V uC SMBus IO
6. SDA and SCL pins connect pullup resistor to VDD for 3.3-V uC SMBus IO
7. Any 4-Level input which requires a connection to "Logic 1" should use a 1-kΩ resistor to VIN
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3.3-V or 2.5-V Supply Mode Operation (continued)
3.3V mode
2.5V mode
VDD_SEL
Enable
VDD_SEL
open
VIN
open
Disable
3.3V
Internal
voltage
regulator
1 uF
VIN
10 uF
2.5V
VDD
VDD
0.1 uF
0.1 uF
VDD
1 uF
2.5V
10 uF
Internal
voltage
regulator
VDD
0.1 uF
0.1 uF
VDD
VDD
0.1 uF
0.1 uF
VDD
VDD
0.1 uF
0.1 uF
VDD
VDD
0.1 uF
0.1 uF
Place 0.1 éF close to VDD Pin
Total capacitance should be 7 0.5 éF
Place capcitors close to VDD Pin
Figure 14. 3.3 V or 2.5 V Supply Connection Diagram
10.2 Power Supply Bypassing
Two approaches are recommended to ensure that the DS80PCI800 is provided with an adequate power supply
bypass. First, the supply (VDD) and ground (GND) pins should be connected to power planes routed on adjacent
layers of the printed circuit board. Second, careful attention to supply bypassing through the proper use of
bypass capacitors is required. A 0.1-μF bypass capacitor should be connected to each VDD pin such that the
capacitor is placed as close as possible to the device. Small body size capacitors (such as 0402) reduce the
parasitic inductance of the capacitor and also help in placement close to the VDD pin. If possible, the layer
thickness of the dielectric should be minimized so that the VDD and GND planes create a low inductance supply
with distributed capacitance.
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11 Layout
11.1 Layout Guidelines
11.1.1 PCB Layout Considerations for Differential Pairs
The differential inputs and outputs are designed with 100 Ω differential terminations. Therefore, they should be
connected to interconnects with controlled differential impedance of approximately 85-110 Ω. It is preferable to
route differential lines primarily on one layer of the board, particularly for the input traces. The use of vias should
be avoided if possible. If vias must be used, they should be used sparingly and must be placed symmetrically for
each side of a given differential pair. Whenever differential vias are used, the layout must also provide for a low
inductance path for the return currents as well. Route the differential signals away from other signals and noise
sources on the printed circuit board. To minimize the effects of crosstalk, a 5:1 ratio or greater should be
maintained between inter-pair spacing and trace width. See AN-1187 Leadless Leadframe Package (LLP)
Application Report (SNOA401) for additional information on QFN (WQFN) packages.
The DS80PCI800 pinout promotes easy high speed routing and layout. To optimize DS80PCI800 performance
refer to the following guidelines:
1. Place local VIN and VDD capacitors as close as possible to the device supply pins. Often the best location is
directly under the DS80PCI800 pins to reduce the inductance path to the capacitor. In addition, bypass
capacitors may share a via with the DAP GND to minimize ground loop inductance.
2. Differential pairs going into or out of the DS80PCI800 should have adequate pair-to-pair spacing to minimize
crosstalk.
3. Use return current via connections to link reference planes locally. This ensures a low inductance return
current path when the differential signal changes layers.
4. Optimize the via structure to minimize trace impedance mismatch.
5. Place GND vias around the DAP perimeter to ensure optimal electrical and thermal performance.
6. Use small body size AC coupling capacitors when possible — 0402 or smaller size is preferred. The AC
coupling capacitors should be placed closer to the Rx on the channel.
Figure 15 depicts different transmission line topologies which can be used in various combinations to achieve the
optimal system performance. Impedance discontinuities at the differential via can be minimized or eliminated by
increasing the swell around each hole and providing for a low inductance return current path. When the via
structure is associated with thick backplane PCB, further optimization such as back drilling is often used to
reduce the detrimental high-frequency effects of stubs on the signal path.
11.2 Layout Example
20 mils
EXTERNAL MICROSTRIP
100 mils
20 mils
INTERNAL STRIPLINE
VDD
VDD
18 17 16 15 14 13 12 11 10
9
8
7
6
5
4
3
2
1
19
54
20
53
52
21
51
22
23
VDD
BOTTOM OF PKG
50
GND
24
49
25
48
26
47
46
27
28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45
VDD
VDD
Figure 15. Typical Routing Options
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12 Device and Documentation Support
12.1 Device Support
12.1.1 Third-Party Products Disclaimer
TI'S PUBLICATION OF INFORMATION REGARDING THIRD-PARTY PRODUCTS OR SERVICES DOES NOT
CONSTITUTE AN ENDORSEMENT REGARDING THE SUITABILITY OF SUCH PRODUCTS OR SERVICES
OR A WARRANTY, REPRESENTATION OR ENDORSEMENT OF SUCH PRODUCTS OR SERVICES, EITHER
ALONE OR IN COMBINATION WITH ANY TI PRODUCT OR SERVICE.
12.2 Trademarks
PCI-Express is a trademark of PCI-SIG.
All other trademarks are the property of their respective owners.
12.3 Electrostatic Discharge Caution
These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam
during storage or handling to prevent electrostatic damage to the MOS gates.
12.4 Glossary
SLYZ022 — TI Glossary.
This glossary lists and explains terms, acronyms, and definitions.
13 Mechanical, Packaging, and Orderable Information
The following pages include mechanical, packaging, and orderable information. This information is the most
current data available for the designated devices. This data is subject to change without notice and revision of
this document. For browser-based versions of this data sheet, refer to the left-hand navigation.
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PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package Pins Package
Drawing
Qty
Eco Plan
(2)
Lead finish/
Ball material
MSL Peak Temp
Op Temp (°C)
(3)
Device Marking
(4/5)
(6)
DS80PCI800SQ/NOPB
ACTIVE
WQFN
NJY
54
2000
RoHS & Green
SN
Level-2-260C-1 YEAR
-40 to 85
DS80PCI800SQ
DS80PCI800SQE/NOPB
ACTIVE
WQFN
NJY
54
250
RoHS & Green
SN
Level-2-260C-1 YEAR
-40 to 85
DS80PCI800SQ
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance
do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may
reference these types of products as "Pb-Free".
RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption.
Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of
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