TI SN75DP130SSRGZT

SN75DP130
SLLSE57 – APRIL 2011
www.ti.com
DisplayPort™1:1 Re-Driver with Link Training
Check for Samples: SN75DP130
FEATURES
APPLICATIONS
•
•
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•
•
1
2
•
•
•
•
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•
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Supports DP v1.1a and DP v1.2 Signaling
Including HBR2 Data Rates to 5.4Gbps
Supports HDMI 1.4a with TMDS Clock
Frequencies up to 340MHz
Glue-Less interface to AMD, Intel, and NVIDIA
Graphics Processors
Auto-Configuration Through Link Training
Output Signal Conditioning with Tunable
Voltage Swing and Pre-Emphasis Gain
Highly Configurable Input Variable Equalizer
Two Device Options Including a Dual Power
Supply Configuration for Lowest Power
2kV ESD HBM Protection
Temperature Range: 0°C to 85°C
48 Pin 7mm × 7mm QFN Package
Notebook PC
Desktop PC
PC Docking Station
PC Standalone Video Card
DESCRIPTION
The SN75DP130 is a single channel DisplayPort™ (DP) re-driver that regenerates the DP high speed digital link.
The device complies with the VESA DisplayPort Standard Version 1.2, and supports a four lane Main Link
interface signaling up to HBR2 rates at 5.4Gbps per lane, and supports DP++ Dual-Mode; offering TMDS
signaling for DVI and full HDMI Version 1.4a support.
The device compensates for PCB related frequency loss and switching related loss to provide the optimum DP
electrical performance from source to sink. The Main Link signal inputs feature configurable equalizers with
selectable boost settings. At the Main Link output, four primary levels of differential output voltage swing (VOD)
and four primary levels of pre-emphasis are available, as well as a secondary level of boost adjustment,
programmed through I2C, for fine-tuning the Main Link output. The device can monitor the AUX channel and
automatically adjust the output signaling levels and input equalizers in response to Link Training commands.
Additionally, the SN75DP130 output signal conditioning and EQ parameters are fully programmable through the
I2C interface.
The SN75DP130 offers separate AUX and DDC source interfaces that connect to a single AUX sink channel.
This minimizes component count when implemented with a graphics processor (GPU) comprising separate DDC
and AUX interfaces. For GPUs with combined DDC/AUX, the device can operate as a FET switch to short circuit
the AUX channel AC coupling caps while connected to a TMDS sink device. Other sideband circuits such as Hot
Plug Detect (HPD) are optimized to reduce external components, providing a seamless connection to Intel, AMD,
and NVIDIA graphics processors.
The SN75DP130 is optimized for mobile applications, and contains activity detection circuitry on the Main Link
input that transitions to a low-power Output Disable mode in the absence of a valid input signal. Other low power
modes are supported, including a Standby mode with typical dissipation of ~2mW when no video sink (e.g.,
monitor) is connected.
The device is characterized for an extended operational temperature range from 0°C to 85°C.
1
2
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas
Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
DisplayPort is a trademark of VESA Standards Association.
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does not
necessarily include testing of all parameters.
Copyright © 2011, Texas Instruments Incorporated
SN75DP130
SLLSE57 – APRIL 2011
www.ti.com
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.
TYPICAL IMPLEMENTATIONS
The configuration shown in Figure 1 supports a GPU with unified AUX/DDC interfaces. This circuit provides back
current protection into the GPU AUX, HPD, and CAD inputs.
DP++ MultiMode Source Side Re-driver; GPU w/ Unified DDC & AUX Outputs;
AUX & DDC Internal Mux Utilized; AUX Channel Monitored for Link Training
SN75DP130
4 diff
MAIN[3:0]
HPD_SRC
HPD
4 diff
OUT[3:0]
IN[3:0]
DP Connector
GPU
HPD_SNK
CAD_SNK
DDC
DDC
AUXSNKAUXSNK+
AUXSRCAUXSRC+
AUX
1M
3.3V
RI2C
RI2C
100kW
100kW
SCL_CTL
SDA_CTL
I2C
3.3V
Optional I2C interface may be used to fully
configure output signal conditioning and
EQ settings. 10kW resistors are
recommended for RI2C.
100kWresistors shall be placed on the AUXSNK side to
ensure proper device internal channel biasing, and to
ensure the sink device identifies the source during power
down conditions.
Figure 1. DP++ Dual-Mode in a Unified AUX/DDC Configuration
The configuration shown in Figure 2 supports a GPU with separate DDC and AUX interfaces, and overcomes the
need for an external AUX to DDC switch. This circuit provides back current protection into the GPU AUX, HPD,
and CAD inputs.
DP++ MultiMode Source Side Re-driver; GPU w/ Separate DDC & AUX Outputs;
AUX & DDC Internal Mux Utilized; AUX Channel Monitored for Link Training
SN75DP130
4 diff
IN[3:0]
MAIN[3:0]
HPD
3.3V
RDDC
HPD_SRC
4 diff
OUT[3:0]
DP Connector
GPU
HPD_SNK
CAD_SNK
RDDC
DDC
DDC
AUX
AUXSRCAUXSRC+
AUXSNKAUXSNK+
1M
3.3V
RI2C
I2C
RI2C
100kW
100kW
SCL_CTL
SDA_CTL
3.3V
The use of RDDC is optional. The SN75DP130
integrates 60kWpullups and a cable adapter
should include 2kWpullup for each line. If it is
uncertain if the cable adapter includes 2kW
pullup resistance, use 10kWfor RDDC.
Optional I2C interface may be used to
fully configure output signal
conditioning and EQ settings. 10kW
resistors are recommended for RI2C.
100kWresistors shall be placed on the AUXSNK side to
ensure proper device internal channel biasing, and to
ensure the sink device identifies the source during power
down conditions.
Figure 2. DP++ Dual-Mode in a Split AUX and DDC Configuration
2
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BLOCK DIAGRAM
VCC
CAD_SRC
CADout
CAD_SNK
CADin
HPD_SNK
HPDin
ADDR_EQ
ADDR_EQ
RinHPD
HPD_SRC
VDDD
~130k
HPDout
RRST=150k
VCC
VDDD (VCORE)
GND
RSTN
EN
RESET
IN
VREG
EN
OUT
REN=200k
VIterm
VBIAS
VCC
50
50
50
IN0p
EQ
IN0n
50
OUT0p
DP++
Driver
OUT0n
VIterm
50
VBIAS
50
50
50
IN1p
EQ
OUT1p
DP++
Driver
IN1n
OUT1n
VIterm
50
VBIAS
50
50
50
IN2p
EQ
IN2n
OUT2p
DP++
Driver
VIterm
50
OUT2n
VBIAS
50
50
IN3p
EQ
50
OUT3p
DP++
Driver
IN3n
OUT3n
AMPL
PRE_EMP
OE
ADDR_EQ
SCL_CTL
SDA_CTL
HPDout
ctrl[3:1]
I2C
Target
CADin
HPDin
EN
ADDR_EQ
vcc
EQ Control
OE
CTRL
CADout
AEQ(Lx)
CADin
Registers
RDDC
PRE_EMP
CADin
RDDC
SCL_DDC
SDA_DDC
DPCD
Training
Logic
AMPL
PRE_EMP
ctrl2
ctrl1
AUX_SRCp
AUX_SRCn
AUX_SNKp
AUX_SNKn
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NC
VCC
AUX_SNKn
28 27
EN
30 29
AUX_SNKp
AUX_SRCp
AUX_SRCn
GND
31
SDA_DDC
35 34 33 32
SCL_DDC
VCC
36
37
RSTN
VCC
TERMINAL ASSIGNMENTS
26 25
24
GND
IN0p
38
23
OUT0p
IN0n
39
22
OUT0n
NC
40
21
NC
IN1p
41
20
OUT1p
19
OUT1n
IN1n
42
NC
43
IN2p
SN75DP130SS
GND
44
17
OUT2p
IN2n
45
16
OUT2n
NC
46
15
NC
IN3p
47
14
OUT3p
IN3n
48
1
13
12
OUT3n
3
4
5
6
7
8
9
10 11
ADDR_EQ
SCL_CTL
SDA_CTL
VCC
NC
CAD_SRC
HPD_SRC
CAD_SNK
HPD_SNK
2
VDDD_DREG
VCC
(TOP VIEW)
VCC
18
VDDD
28 27
VDDD
EN
AUX_SNKn
30 29
AUX_SNKp
AUX_SRCp
AUX_SRCn
GND
31
SCL_DDC
35 34 33 32
SDA_DDC
VDDD
36
37
RSTN
VCC
Figure 3. SN75DP130SS Single Supply
26 25
24
GND
41
20
OUT1p
IN1n
42
SN75DP130DS
19
OUT1n
VDDD
43
(TOP VIEW)
18
GND
IN2p
44
17
OUT2p
IN2n
45
16
OUT2n
NC
46
15
VDDD
IN3p
47
14
OUT3p
IN3n
48
1
13
12
OUT3n
3
4
5
6
7
8
9
10 11
HPD_SNK
2
VDDD
VDDD
IN1p
CAD_SNK
21
HPD_SRC
40
CAD_SRC
OUT0n
NC
NC
22
VDDD
39
SCL_CTL
IN0n
SDA_CTL
OUT0p
ADDR_EQ
23
VDDD_DREG
38
VCC
IN0p
Figure 4. SN75DP130DS Dual Supply
4
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PIN FUNCTIONS
PIN
NAME
I/O
NO.
DESCRIPTION
MAIN LINK TERMINALS
IN0p, IN0n
38, 39
Input
(100Ω diff)
DisplayPort Main Link Lane 0 Differential Input
IN1p, IN1n
41, 42
IN2p, IN2n
44, 45
IN3p, IN3n
47, 48
OUT0p, OUT0n
23, 22
OUT1p, OUT1n
20, 19
OUT2p, OUT2n
17, 16
DisplayPort Main Link Lane 2 Differential Output
OUT3p, OUT3n
14, 13
DisplayPort Main Link Lane 3 Differential Output
DisplayPort Main Link Lane 1 Differential Input
DisplayPort Main Link Lane 2 Differential Input
DisplayPort Main Link Lane 3 Differential Input
Output
(100Ω diff)
DisplayPort Main Link Lane 0 Differential Output
DisplayPort Main Link Lane 1 Differential Output
AUX CHANNEL AND DDC DATA TERMINALS
AUX_SRCp,
AUX_SRCn
30, 29
I/O
(100Ω diff)
Source Side Bidirectional DisplayPort Auxiliary Data Channel. If the AUX_SNK
channel is used for monitoring only, these signals are not used and may be left open.
AUX_SNKp, AUX_SNKn
28, 27
I/O
(100Ω diff)
Sink Side Bidirectional DisplayPort Auxiliary Data Channel.
SCL_DDC, SDA_DDC
33, 34
I/O
Bidirectional I2C Display Data Channel (DDC) for TMDS mode. These signals may be
utilized together with AUX_SNK to form a FET switch to short-circuit the AC coupling
capacitors during TMDS operation in a DP++ Dual-Mode configuration. These
terminals include integrated 60 kΩ pull-up resistors
HPD, CAD, and CONTROL TERMINALS
HPD_SRC
9
O
Hot Plug Detect Output to the DisplayPort Source.
HPD_SNK
11
I
DisplayPort Hot Plug Detect Input from Sink. This device input is 5V tolerant.
Note: Pull this input high during compliance testing or use I2C control interface to go
into compliance test mode and control HPD_SNK and HPD_SRC by software.
CAD_SRC
8
O
DP Cable Adapter Detect Output. This output typically drives the GPU CAD input.
CAD_SNK
10
I
DisplayPort Cable Adapter Detect Input. This input tolerates a 5V supply with a supply
impedance higher than 90kΩ. A device internal zener diode limits the input voltage to
3.3V.
An external 1MΩ resistor to GND is recommended. This terminal is used to select DP
mode or TMDS mode in a DP++ Dual-Mode application.
SCL_CTL, SDA_CTL
4, 5
I/O
RSTN
35
I
Bidirectional I2C interface to configure the SN75DP130. This interface is active
independent of the EN input but inactive when RSTN is low.
Active Low Device Reset. This input includes a 150kΩ resistor to the VDDD core
supply. An external capacitor to GND is recommended on the RSTN input to provide a
power-up delay.
This signal is used to place the SN75DP130 into Shutdown mode for the lowest power
consumption. When the RSTN input is asserted, all outputs (excluding HPD_SRC and
CAD_SRC) are high-impedance, and inputs (excluding HPD_SNK and CAD_SNK) are
ignored; all I2C and DPCD registers are reset to their default values.
At power up, the RSTN input must not be de-asserted until the VCC and VDDD
supplies have reached at least the minimum recommended supply voltage level.
EN
26
ADDR_EQ
3
I
Device Enable. This input incorporates an internal pullup of 200kΩ.
3-level Input I2C Target Address Select and EQ Configuration Input. If the I2C bus is used, this
input setting selects the I2C target address, as described in Table 7. This input also
configures the input EQ to the device, as described in Table 5.
SUPPLY AND GROUND TERMINALS
VDDD
VCC
SN75DP130DS
Digital low voltage core and Main Link supply for SN75DP130DS device option.
6, 12, 15, 21, 25, 32, 37, Nominally 1.1V.
43
SN75DP130SS
1, 6, 12, 25, 32, 36
3.3V Supply
SN75DP130DS
1, 36
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PIN FUNCTIONS (continued)
PIN
NAME
I/O
NO.
VDDD_DREG
7
GND
18, 24, 31, 37, 43, and
Exposed Thermal Pad
NC
SN75DP130SS
15, 21, 37, 43
DESCRIPTION
SN75DP130SS: Digital voltage regulator decoupling; install 1µF to GND.
SN75DP130DS: Treat same as VDDD; this pin will be most noisy of all VDDD
terminals and needs a de-coupling capacitor nearby.
Ground. Reference GND connections include the device package exposed thermal
pad.
No Connect. These terminals may be left unconnected, or connect to GND.
SN75DP130DS
7, 40, 47
ORDERING INFORMATION (1)
(1)
PART NUMBER
PART MARKING
PACKAGE
SN75DP130DSRGZR
DP130DS
48-pin QFN reel
SN75DP130SSRGZR
DP130SS
48-pin QFN reel
SN75DP130DSRGZT
DP130DS
48-pin QFN small quantity tape
SN75DP130SSRGZT
DP130SS
48-pin QFN small quantity tape
For the most current package and ordering information, see the Package Option Addendum at the end of this document, or see the TI
web site at www.ti.com.
ABSOLUTE MAXIMUM RATINGS
over operating free-air temperature range (unless otherwise noted)
Supply voltage
range
Voltage range
(1)
VALUE
UNIT
VCC
–0.3 to 4.0
V
VDDD, VDDD_DREG
–0.3 to 1.3
V
Main link I/O differential voltage
–0.3 to 1.3
V
HPD_SNK
–0.3 to 5.5
V
–0.3 to 4
V
All other terminals
–65 to 150
°C
Main Link I/O, AUX_SNK, HPD_SNK, CAD_SNK
±2
kV
All Other Terminals
±2
kV
±500
V
Storage temperature TS
Electrostatic
discharge
Human Body
Model (2)
Charged-device model
(1)
(2)
(3)
(3)
Stresses beyond those listed under absolute maximum ratings may cause permanent damage to the device. These are stress ratings
only and functional operation of the device at these or any conditions beyond those indicated under recommended operating conditions
is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
Tested in accordance with JEDEC Standard 22, Test Method A114-B
Tested in accordance with JEDEC Standard 22, Test Method C101-A
THERMAL INFORMATION
THERMAL METRIC (1)
SN75DP130
QFN (48) PINS
θJA
Junction-to-ambient thermal resistance
35.1
θJCtop
Junction-to-case (top) thermal resistance
21.5
θJB
Junction-to-board thermal resistance
11.7
ψJT
Junction-to-top characterization parameter, high-k board
1.2
ψJB
Junction-to-board characterization parameter, high-k board
11.9
θJCbot
Junction-to-case (bottom) thermal resistance
6.7
(1)
6
UNITS
°C/W
For more information about traditional and new thermal metrics, see the IC Package Thermal Metrics application report, SPRA953.
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POWER DISSIPATION
TEST CONDITIONS (1)
PARAMETER
PN
Device power under normal operation
PSD
Standby mode power dissipation
PD3
D3 power down mode dissipation
POD
(1)
MIN
MAX
UNIT
468
828
mW
SN75DP130DS; 4 DP Lanes.
172
304
mW
14.4
mW
SN75DP130DS; 4 DP Lanes.
7.2
mW
SN75DP130SS; 4 DP Lanes.
14.4
mW
SN75DP130DS; 4 DP Lanes.
7.2
mW
SN75DP130SS; 4 DP Lanes.
54
mW
SN75DP130DS; 4 DP Lanes.
46
mW
SN75DP130SS; 4 DP Lanes.
Shutdown mode power dissipation
PSBY
TYP
SN75DP130SS; 4 DP Lanes.
Output disable (squelch) mode current
SN75DP130SS; 4 DP Lanes.
126
180
mW
SN75DP130DS; 4 DP Lanes.
58
88
mW
UNIT
Test conditions correspond to Power Supply test conditions in Electrical Characteristics
RECOMMENDED OPERATING CONDITIONS
VCC
Supply voltage
VDDD
Digital core and Main Link supply voltage
TA
Operating free-air temperature
TCASE
Case temperature
VIH(HPD)
High-level input voltage HPD_SNK
VIH
VIL
MIN
NOM
MAX
3
3.3
3.6
V
0.97
1.05
1.2
V
85
°C
103.1
°C
1.9
5.5
V
High-level input voltage for device control signals
1.9
3.6
V
Low-level input voltage for device control signals
0
0.8
V
0.30
1.40
Vpp
5.4
Gbps
200
nF
120
Ω
2
V
0
MAIN LINK TERMINALS
VID
Peak-to-peak input differential voltage; RBR, HBR, HBR2
dR
Data rate
CAC
AC coupling capacitance (each input and each output line)
75
Rtdiff
Differential output termination resistance
80
VOterm
Output termination voltage (AC coupled)
0
tSK(in
HBR2)
Intra-pair skew at
the input at 5.4Gbps
tSK(in
HBR)
Intra-pair skew at the input at 2.7Gbps
100
ps
tSK(in
RBR)
Intra-pair skew at the input at 1.62Gbps
300
ps
100
When used as re-driver in DP source
20
When used as receiver equalizer in DP sink
100
ps
AUX CHANNEL DATA TERMINALS
AUX_SRCp and AUX_SNKp in DP mode
VI-DC
DC input voltage
AUX_SRCn and AUX_SNKn in DP mode
AUX_SRCp/n and AUX_SNKp/n in TMDS mode
-0.5
0.3
0.4
2.0
3.0
3.6
V
-0.5
3.6
1400
mVPP
1.2
Mbps
VID
Differential input voltage amplitude (DP mode only)
300
dR(AUX)
Data rate (before Manchester encoding)
0.8
dR(FAUX)
Data rate Fast AUX (300ppm frequency tolerance)
tjccin_adj
Cycle-to-cycle AUX input jitter adjacent cycle (DP mode only)
tjccin
Cycle-to-cycle AUX input jitter within one cycle (DP mode only)
CAC
AUX AC coupling capacitance (DP mode only)
VsrcCMM
AUX source common mode voltage (only applies to DP mode)
CAD = VIL; measured on AUX source and sink before AC coupling caps
1
720
Mbps
0.05
UI
0.1
UI
75
200
nF
0
2000
mV
DDC AND I2C TERMINALS
VI
Input voltage
dR
Data rate
VIH
High-level input voltage
VIL
Low-level input voltage
-0.5
3.6
V
100
kbps
0.7VCC
V
0.3VCC
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RECOMMENDED OPERATING CONDITIONS (continued)
MIN
NOM
MAX
UNIT
100
kHz
fSCL
SCL clock frequency standard I2C mode
tw(L)
SCL clock low period standard I2C mode
4.7
µs
tw(H)
SCL clock high period standard I2C mode
4.0
µs
Cbus
Total capacitive load for each bus line
400
pF
POWER SUPPLY ELECTRICAL CHARACTERISTICS
over recommended operating conditions (unless otherwise noted)
PARAMETER (1)
ICCDP1HBR2
ICCDP2HBR2
ICCDP4HBR2
TEST CONDITIONS
MIN
Supply Current 1 DP Lanes Maximum conditions: IN/OUT at 5.4Gbps
Supply Current 2 DP Lanes PRBS,VOD = 510mVpp, PE = 6dB; AUX at 1Mbps
PRBS, VID = 1000mVpp; EQ = 3dB
Typical Conditions: IN/OUT at 5.4Gbps
Supply Current 4 DP Lanes PRBS,VOD = 510mVpp, PE = 0dB AUX and I2C
Idle; EQ = 3dB
TYP
70
mA
70
125
mA
130
230
mA
Supply Current 1 DP Lanes
ICCDP2HBR
Supply Current 2 DP Lanes
ICCDP4HBR
Supply Current 4 DP Lanes
ICCTMDS
Supply Current TMDS
Mode
Main Link at 2.5Gbps PRBS, VID = VOD = 600mVpp;
AUX Idle
ISD
Shutdown supply current
Shutdown mode
ISBY
Standby supply current
Standby mode
ID3
D3 supply current
D3 power down mode
IOD
Squelch supply current
Output disable (Squelch) mode
35
(1)
UNIT
40
ICCDP1HBR
Main Link at 2.7Gbps PRBS, VOD =510mVpp,
PE = 0dB; AUX and I2C Idle; EQ at 3dB fixed gain
MAX
40
mA
70
mA
130
mA
170
mA
4
mA
3
4
mA
10
15
mA
50
mA
3
Values are VDDD supply measurements; VCC supply (DS package option) measurements are 5mA (typical) and 8mA (max), with zero
current in shutdown and standby modes.
MAIN LINK ELECTRICAL CHARACTERISTICS
over recommended operating conditions (unless otherwise noted)
PARAMETER
MIN
TYP
MAX
UNIT
VOD(L0)
238
340
442
mVPP
VOD(L1)
357
510
663
mVPP
484
690
897
mVPP
700
1000
1300
mVPP
420
600
780
mVPP
1.7
3.5
5.3
dB
1.6
2.5
3.5
dB
0.8
3.5
6.0
dB
0
0.25
dB
VOD(L2)
Output differential voltage swing
TEST CONDITIONS
VPRE(L0); 675Mbps D10.2 Test Pattern; BOOST=01
VOD(L3)
VOD(TMDS)
675Mbps D10.2 Test Pattern; BOOST=01
ΔVOD(L0L1)
ΔVOD(L1L2)
Output peak-to-peak differential
voltage delta
ΔVOD(L2L3)
ΔVODn = 20×log(VODL(n+1) / VODL(n)) measured in
compliance with PHY CTS1.1D15 section 3.2 at
test point TP2 using special CTS test board
VPRE(L0)
All VOD options
VPRE(L1)
VOD = VOD(L0), VOD(L1), or VOD(L2); BOOST=01
3.5
dB
VOD = VOD(L0) or VOD(L1); BOOST=01
6.0
dB
VOD = VOD(L0); BOOST=01
9.5
dB
10%
dB
–10%
dB
VPRE(L2)
Driver output pre-emphasis
(default)
VPRE(L3)
VPRE(BOOST)
Output VPRE boost
ΔVPRE(L1L0)
ΔVPRE(L2L1)
Pre-emphasis delta
ΔVPRE(L3L2)
ΔVConsBit
8
Non-transition bit voltage
variation
BOOST=10
BOOST=00
Measured in compliance with PHY CTS1.1D15
section 3.3 at test point TP2 using special CTS test
board
See CTS spec section 3.3.5
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2.0
dB
1.6
dB
1.6
dB
30%
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MAIN LINK ELECTRICAL CHARACTERISTICS (continued)
over recommended operating conditions (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
AEQ(HBR)
Equalizer gain for RBR/HBR
AEQ(HBR2)
Equalizer gain for HBR2
AEQ(TMDS)
Equalizer gain for TMDS
ROUT
Driver output impedance
RIN
Input termination impedance
VIterm
Input termination voltage
VOCM(SS)
Steady state output
common-mode voltage
ΔVOCM(SS)
Change in steady state output
common-mode voltage between
logic levels
Tested in compliance to section 3.10 in CTS 1.1a
VOCM(PP)
Output common-mode noise
HBR2
VSQUELCH
Squelch threshold voltage
Programable via I2C; default at 80mVpp typical
ITXSHORT
Short circuit current limit
Main Link outputs shorted to GND
TYP
MAX
See Table 5 and Table 8 for EQ setting details;
Max value represents the typical value for the
maximum configurable EQ setting
UNIT
9
dB
18
dB
3
dB
Ω
50
60
Ω
0
2
V
0
2
V
40
AC coupled; self-biased
50
10
mVPP
20
mVRMS
30
mVRMS
80
mVPP
50
mA
MAIN LINK SWITCHING CHARACTERISTICS
over recommended operating conditions (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
tPD
Propagation delay time
See Figure 5
tSK(1)
Intra-pair output skew
tSK(2)
Inter-pair output skew
Signal input skew = 0ps; dR = 2.7Gbps, VPRE = 0dB,
800mVp-p, D10.2 clock pattern at device input; See
Figure 6
Δtjit
VOD(L0); VPRE(L0); EQ = 8dB; clean source; minimum input
Total peak-to-peak residual jitter and output cabling; 1.62Gbps, 2.7Gbps, and 5.4Gbps
PRBS7 data pattern.
tsq_enter
Squelch entry time
Time from active DP signal turned off to ML output off with
noise floor minimized
tsq_exit
Squelch exit time
Time from DP signal on to ML output on
VOD
tF
tR
TYP
MAX
300
UNIT
ps
20
ps
100
ps
15
ps
10
120
μs
0
1
μs
100%
80%
0V
VOCM
20%
0%
VOCM(pp)
DVOCM(ss)
D+
VIterm
0V to 2V
D-
50 W
50 W
50 W
50 W
D+
VD+
Receiver
VID
D-
Driver
Y
100pF
VY
Z
VD-
100pF
VZ
VID = VD+ - VD-
VOD = VY - VZ
VICM = (VD+ + VD-)
2
VOCM = (VY + VZ)
2
Figure 5. Main Link Test Circuit
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tOUTxp(f)
tOUTxp(r)
tOUTxn(f)
tOUTxn(r)
OUTxp
50%
OUTxn
tsk1 = 0.5 x | (tOUTxp(r)-tOUTxn(f)) + (tOUTxp(f)-tOUTxn(r)) |
tsk2
OUTyp
OUTyn
Figure 6. Main Link Skew Measurements
HPD/CAD ELECTRICAL CHARACTERISTICS
over recommended operating conditions (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP MAX
UNIT
HPD_SRC, CAD_SRC
VOH
High-level output voltage
IOH = 500µA
2.7
3.6
V
VOL
Low-level output voltage
IOH = 500µA
0
0.1
V
RoutCAD
CAD series output resistance
RoutHPD
HPD series output resistance
ILEAK
Leakage current
(1)
(2)
EN=RSTN=VCC; HPD_SNK=CAD_SNK=VCC
150
EN=RSTN=VCC; HPD_SNK=CAD_SNK=VCC
150
Ω
Ω
VCC= 0V, V(pin) = 1.2V; RSTN
20
VCC= 0V, V(pin) = 3.3V; SCL/SDA_CTL,
AUX_SNKp/n
20
VCC= 0V, V(pin) = 3.3V; HPD_SNK
40
VCC= 0V, V(pin) = 3.3V; AUX_SRCp/n
60
μA
HPD_SNK
IH
High-level input current
VIH = 1.9V (leakage includes the 130kΩ pull-down
resistor)
–30
30
µA
IL
Low-level input current
VIL = 0.8V (leakage includes the 130kΩ pull-down
resistor)
–30
30
µA
VTH+
Positive going input threshold voltage
RpdHPD
HPD input termination to GND
VCC=0V
IH
High-level input current
VIH = 1.9V
IL
Low-level input current
VIL = 0.8V
VTH+
Positive going input threshold voltage
1.4
100
130
V
160
kΩ
–1
1
µA
–1
1
µA
CAD_SNK
(1)
(2)
1.4
V
A series output resistance of 100kΩ may be added in series to the CAD_SRC output to mimic a cable adapter.
Applies to failsafe inputs: RSTN, SDA_CTL, SCL_CTL, SDA_DDC, SCL_DDC, AUX_SNK P/N, AUX_SRC P/N, HPD_SNK
HPD/CAD SWITCHING CHARACTERISTICS
over recommended operating conditions (unless otherwise noted)
PARAMETER
TEST CONDITIONS
tPD(HPD)
Propagation delay HPD_SNK to HPD_SRC
tPD(CAD)
Propagation delay CAD_SNK to CAD_SRC
tT(HPD)
HPD logic shut off time
10
VCC = 3.0V; See Figure 8
VCC = 3.0V; See Figure 9
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MIN
TYP
MAX
UNIT
50
ns
50
ns
400
ms
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TP
HPD_SRC
HPD_SNK
TP
130 KW
100 KW
SN75DP130
Figure 7. HPD Test Circuit
VCC
HPD_SNK
HPD_SNK
VCC
50%
50%
0V
Sink Hot Plug
Detect Timeout
t T(HPD)
0V
tPD(HPD)
VCC
VOH
HPD_SRC
50%
HPD_SRC
VOL
Device active
50%
Low power
0V
Figure 8. HPD Timing Diagram 1
Figure 9. HPD Timing Diagram 2
AUX/DDC/I2C ELECTRICAL CHARACTERISTICS
over recommended operating conditions (unless otherwise noted)
PARAMETER
TEST CONDITIONS
VPASS
DDC mode passthrough voltage
VCAD_SNK = VIH; IO = 100 µA
CIO
I/O capacitance
VIO = 0 V; f(test) = 1 MHz
On resistance AUX_SRCn to AUX_SNKn in DP
mode
VCC = 3.0 V w/ VI =2.85V or
VCC = 3.6 V w/ VI = 3.4 V; IO = 5 mA
On resistance SCL/SDA_DDC to AUX_SNK in
TMDS mode
MIN
TYP
MAX
1.9
UNIT
V
10
pF
5
10
Ω
IO = 3 mA
15
30
Ω
On resistance AUX_SRC to AUX_SNK in TMDS
mode
IO = 3 mA
10
20
Ω
ΔrON
On resistance variation with input signal voltage
change in DP mode
VCC = 3.6 V, IO = 5 mA, VI = 2.6 to 3.4 V,
VCC = 3.0 V, IO = 5 mA, VI = 0 to 0.4 V
5
Ω
VID(HYS)
Differential input hysterisis
By design (simulation only)
IH
High-level input current
VI = VCC
-5
5
VI = GND; CAD_SNK = VIH
-5
5
rON
50
mV
µA
µA
IL
Low-level input current
VAUX+
Voltage on the Aux+ for PHY-CTS 3.19
1M (5%) pullup to VCC and 100kΩ pulldown to GND on
AUX+; VCC = 3.3 V
0
0.4
V
VAUX-
Voltage on the Aux- for PHY-CTS 3.18
100kΩ pullup to VCC and 1M (5%) pulldown to GND on
AUX-;
VCC = 3.3 V
2.4
3.6
V
|S1122|
Differential line insertion loss
VID = 400 mV, AC coupled; p-channel biasing 0.3 V and
n-channel 3.0V; 360 MHz sine wave; CAD_SNK=VIL
1.6
3
dB
RDDC
Switcheable pul-lup resistor on DDC at source
side (SCL_DDC, SDA_DDC)
CAD_SNK = VIH
60
72
kΩ
VI = GND; At DDC inputs
80
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AUX/DDC/I2C SWITCHING CHARACTERISTICS
over recommended operating conditions (unless otherwise noted)
PARAMETER
TEST CONDITIONS
TYP
VID = 400 mV, AC coupled; p-channel biasing 0.3V and
n-channel 3.0V; See Figure 10
tsk(AUX)
Intra-pair skew
tPLH(DP)
Propagation delay time, low to high
tPHL(DP)
Propagation delay time, high to low
tPLH(DDC)
Propagation delay time, low to high
tPHL(DDC)
Propagation delay time, high to low
tPU(AUX)
MIN
CAD = VIL; 1Mbps pattern;See Figure 11
CAD = VIH; 100kbps pattern
VID = 0.1 V, VICMM = 2 V source side (before AC
coupling caps)
Main Link D3 wakeup time
MAX
UNIT
400
ps
3
ns
3
ns
50
ns
50
ns
50
µs
I2C
Refer to the I2C-Bus Specification, Version 2.1 (January 2000); SN75DP130 meets the switching characteristics for standard mode
transfers up to 100 kbps.
2 .2V
2.2 V
AUX Input
1.8 V
50 %
Differential
0V
AUX Input
t PHL (AUX)
1.8V
t PLH(AUX)
Differential
AUX Output 0 V
t sk(AUX )
Figure 10. AUX Skew Measurement
Figure 11. AUX Delay Measurement
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TYPICAL CHARACTERISTICS
A. Gain represents SN75DP130 design simulation
Figure 12. Typical EQ Gain Curves
A. DisplayPort output jitter measured at the surface mount pins
connected to the main link output channels on the SN75DP130
characterization test board; input jitter generated from test board
with variable input trace lengths using 4 mil traces of lengths 2
inches to 22 inches generating the typical input jitter as represented
in Table 1.
Figure 13. DisplayPort Sink Jitter Performance with
Optimal EQ Settings
Table 1. Characterization Test Board Trace Lengths Related to Input Jitter
INPUT MODE
Display Port HBR2
TMDS 3.4 Gbps
TRACE LENGTH (inches)
TOTAL INPUT JITTER (ps)
RECOMMENDED EQ SETTING
2
14.4
8
6
23.1
8
10
38.8
10
14
58.9
10
18
84.8
13
22
13.9
13
2
15.8
6
6
6
21.3
10
33.2
6
14
49.9
13
18
70.5
13
22
91.5
13
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A. DisplayPort output jitter measured at the surface mount pins
connected to the main link output channels on the SN75DP130
characterization test board; input jitter generated from test board
with variable input trace lengths using 4 mil traces of lengths 2
inches to 22 inches generating the typical input jitter as represented
in Table 1.
Figure 14. TMDS Sink jitter Performance with Optimal EQ
Settings
Figure 16. SN75DP130 Output; 10 inch Input Trace; 13dB
EQ Setting; DP Sink
14
Figure 15. Main Link Input with 10 inch Trace; DisplayPort
Sink
Figure 17. Main Link Input with 10 inch Trace; TMDS Sink
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Figure 18. SN75DP130 Output; 10 inch Input Trace; 13dB EQ Setting; TMDS Sink
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APPLICATION INFORMATION
ADDITIONAL TYPICAL IMPLEMENTATIONS
Theconfiguration shown in Figure 19 is preferred to avoid very long AUX signal stub lines. Furthermore, this
configuration provides isolation between the DP connector and the GPU.
DP Only Source Side Re-driver; Buffered AUX Channel (no stub lines);
AUX Channel Monitored for Link Training
4 diff
MAIN[3:0]
SN75DP130
IN[3:0]
HPD
4 diff
OUT[3:0]
HPD_SRC
DP Connector
GPU
HPD_SNK
3.3V
RI2C
AUXSNKAUXSNK+
RI2C
SCLSDA+
SCL_CTL
SDA_CTL
100n
AUXAUX+
AUXSRCAUXSRC+
100kW
100n
Optional I2C interface may be used to fully
configure output signal conditioning and
EQ settings. 10kW resistors are
recommended for RI2C.
100kW
3.3V
100kWresistors shall be placed on the AUXSNK side to
ensure proper device internal channel biasing, and to
ensure the sink device identifies the source during power
down conditions.
CAD_SNK = VIL
Figure 19. DP Only Configuration with AUX Pass Through
The configuration shown in Figure 20 enables the SN75DP130 in DP++ Dual-Mode with the AUX input only
monitoring the AUX channel. Use this setting when AUX stub lines can be kept short and minimum AUX
attenuation is desired. For DP v1.1a, the stub length shall not exceed 4cm each, and for DP v1.2 with FAUX
support each stub line shall be shorter than 1cm.
DP++ MultiMode Source Side Re-driver; GPU w/ Unified DDC & AUX Outputs;
AUX Channel Monitored for Link Training
SN75DP130
4 diff
MAIN[3:0]
IN[3:0]
HPD
4 diff
OUT[3:0]
HPD_SRC
HPD_SNK
CAD
CAD_SRC
CAD_SNK
SCLSDA+
SCL_CTL
SDA_CTL
DDC
AUX
AUXSNKAUXSNK+
CAD
CAD
1M
DP connector
GPU
3.3V
100kW
CAD
Optional I2C interface may be used to
fully configure output signal
conditioning and EQ settings. 10kW
resistors are recommended for RI2C.
100kW
Minimize Stub Line Length
Figure 20. DP++ Dual-Mode Configuration with AUX Monitor
The alternate configuration shown in Figure 21 allows a reduced BOM by eliminating the need for external FET
switches while routing AUX and DDC externally, which eliminates any insertion loss cases of AUX is brought
through the SN75DP130. For DP v1.2 with FAUX support each stub line shall be shorter than 1cm.
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DP++ MultiMode Source Side Re-driver; AUX Channel AC Capacitors Short
Circuited in TMDS Mode by Internal FET; AUX Channel Monitored for Link Training
SN75DP130
4 diff
MAIN[3:0]
HPD
IN[3:0]
HPD_SRC
CAD
CAD
CAD_SRC
3.3V
4 diff
OUT[3:0]
HPD_SNK
DP connector
GPU
CAD
CAD_SNK
I2C required to select this
configuration
RI2C
DDC
AUXSNKAUXSNK+
1M
SCL_CTL
SDA_CTL
AUXSRCAUXSRC+
RI2C
SCL
SDA
3.3V
100kW
AUX
I2C interface may be used to fully
configure output signal conditioning
and EQ settings. 10kW resistors are
recommended for RI2C.
Option 1: CAD_OUT drives GPU;
protects back current to GPU.
Option 2: connect CAD signal
from board connector to the GPU.
100kW
Minimize Stub Line Length
Figure 21. Alternate Low-BOM DP++ Dual-Mode Configuration
OPERATING MODES OVERVIEW
special I2C
commands
EN or RSTN low
Power up
Compliance
Test Mode
HPD_SNK low
for >tT(HPD)
EN or RSTN low
Shutdown
Mode
Standby
Mode
D3 Power
Down Mode
EN and RSTN high
HPD_SNK low
for >tT(HPD)
HPD_SNK high;
AUX link
enter D3
training started AUX cmd
(CAD=0)
EN or RSTN low
Active Mode
CAD=0
DP mode
CAD=1
TMDS
mode
invalid DPCD
register entry
Exit D3
AUX cmd
or CAD high
any
e
st a t
DPCD register
corrected
Output
Disable
Mode
Squelch event
Squelch release
Figure 22. SN75DP130 Operating Modes Flow Diagram
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Table 2. Description of SN75DP130 Operating Modes
MODE
CHARACTERISTICS
CONDITIONS
Shutdown Mode
Least amount of power consumption (most circuitry turned off); HPD_SRC
reflects HPD_SNK state; all other outputs are high-impedance; if RSTN is high
local I2C IF remains active; if RSTN is low local I2C interface is turned off, all
other inputs are ignored, and AUX DPCD is reset. (EN=low does not reset
DPCD)
EN or RSTN is low;
Power on default mode
Standby Mode
Low power consumption (I2C IF is active; AUX monitor is inactive); Main Link
outputs are disabled;
EN and RSTN are high;
HPD_SNK low longer than tT(HPD)
Low power consumption (I2C IF is active; AUX monitor active in DP mode); Main
Link outputs are disabled;
EN and RSTN are high;
AUX cmd requested DP sink to
enter D3 power saving mode
D3 Power Down
Mode
Data transfer (normal operation); The device is either in TMDS mode
(CAD_SNK=high) or DP mode (CAD_SNK=low);
Active Mode
In DP mode, the AUX monitor is actively monitoring for Link Training; the output
signal swing and input equalization setting depend on the Link Training or I2C
settings; the AUX SRC channel is active; the AUX SNK and DDC are active
unless disabled through I2C IF. At power-up all Main Link outputs are disabled by
default. AUX Link Training is necessary to overwrite the DPCD registers to
enable Main Link outputs.
EN and RSTN are high;
HPD_SNK is high;
HPD_SNK can also be low for less
than tZ(HPD) (e.g., sink interrupt
request to source)
In TMDS mode the output signal swing is 600mVpp unless this setting is adjusted
by overwriting according registers through I2C IF. Transactions on the AUX lines
will be ignored.
Compliance Test
Mode
Through I2C registers the device can be forced into ignoring HPD_SNK and
CAD_SNK, HPD_SRC and CAD_SRC are programmable; output swing,
pre-emphasis and EQ setting are programmable; automatic power down features
can be disabled
EN and RSTN is high; I2C selects
HPD and/or CAD test mode
Output Disable
Mode
DPCD write commands on the AUX bus detected by the SN75DP130 will also
write to the local DPCD register. The DPCD register should always be written
with a valid entry. If register 101h or 103h is written with a forbidden value, the
SN75DP130 disables the Main Link output signals, forcing the DP sink to issue
an interrupt. The DP source can now re-train the link using valued DPCD register
values. As soon as all DPCD registers contain a valid entry, the SN75DP130
switches back into the appropriate mode of operation.
EN and RSTN are high;
DPCD register 101h or 103h entry is
invalid
Table 3. Description of Operating Mode Transitions
MODE TRANSITION
USE CASE
TRANSITION SPECIFICS
Shutdown → Standby
Activate SN75DP130
EN and RSTN both transitioned high
Standby → Active
Turn on Main Link (DP sink plugged in)
HPD_SNK input asserts high
Active → D3 Power Down
DP source requests temporary power down for
power savings
Receive D3 entry command on AUX
Active → Output Disable
Squelch event; inactive video stream
Main Link monitor detects the inactive video stream
D3 Power Down → Active
Exit temporary power down
Receive D3 exit command on AUX, or CAD_SNK
input is asserted (high)
D3 Power Down → Standby
Exit temporary power down (DP sink unplugged)
HPD_SNK de-asserted to low for longer than tT(HPD)
Active → Standby
Turn off Main Link (DP sink unplugged)
HPD_SNK de-asserted to low for longer than tT(HPD)
Any → Shutdown
Turn off SN75DP130
EN or RSTN transitions low
Any → Output Disable
DPCD register access error condition
Invalid DPCD register access
Output Disable → Active
Squelch released; video stream re-activated
Main Link monitor detects active video stream
Output Disable → Any
DPCD register error condition is corrected
Appropriate operating mode is re-entered
IMPLEMENTING THE RSTN SIGNAL
The SN75DP130 RSTN input gives control over the device reset and to place the device into shut-down mode.
When RSTN is low, all DPCD registers are reset to their default values, and all Main Link lanes are disabled.
When the RSTN input returns to a high logic level, the device comes out of the Shutdown mode. To turn on the
Main Link, it is necessary to either program the DPCD registers through the local I2C interface or to go through a
full sequence of Link Training between DP source and DP sink.
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It is critical to reset the digital logic of the SN75DP130 after the VDDD supply is stable (i.e., VDDD has reached the
minimum recommended operating voltage). This is achieved by asserting the RSTN input from low to high. A
system may provide a control signal to the RSTN signal that transitions low to high after the VDDD supply is
stable, or implement an external capacitor connected between RSTN and GND, to allow delaying the RSTN
signal during power up. The implementations are shown in Figure 23 and Figure 24.
VDDD
Open Drain
Output
RSTN
GPO
C
RSTN
R RSTN = 150 kW
C
Controller
SN75DP130
SN75DP130
Figure 23. External Capacitor Controlled RSTN
Figure 24. RSTN Input from Active Controller
When implementing the external capacitor, the size of the external capacitor depends on the power up ramp of
the VDDD supply where a slower ramp-up results in a larger value external capacitor.
Refer to the latest reference schematic for the SN75DP130 device and/or consider approximately 200nF
capacitor as a reasonable first estimate for the size of the external capacitor.
When implementing a RSTN input from an active controller, it is recommended to use an open drain driver if the
RSTN input is driven. This protects the RSTN input from damage of an input voltage greater than VDDD.
HOT PLUG DETECT (HPD) AND CAD DESCRIPTION
The SN75DP130 generates the Hot Plug Detect (HPD_SRC) signal to indicate to the source that a sink has been
detected. A low HPD_SNK signal input indicates no sink device is connected. When HPD_SNK is high, the
CAD_SNK signal indicates whether a DP sink (CAD_SNK=low) or a TMDS sink (CAD_SNK=high).
A sink device can request a source device interrupt by pulling the HPD_SNK signal low for a duration of 0.5ms to
1.0ms. The interrupt passes through the SN75DP130. If the HPD_SNK signal goes low for longer than 2ms, the
DP source determines that the sink device is disconnected. To conserve power, the SN75DP130 will go into a
power saving Standby mode after the HPD signal went low for a duration of tT(HPD).
In the TMDS mode the AUX training logic is disabled and the Main Link transmits with a fixed output voltage
swing of 600mVpp; the pre-emphasis level is set to 0dB. Output swing and pre-emphasis level are also
adjustable by I2C IF. In TMDS mode all four Main Link output lanes are enabled.
Through the local I2C interface it is also possible to force the device to ignore HPD_SNK and CAD_SNK, and
control HPD_SRC and CAD_SRC directly.
AUX AND DDC CONFIGURATION DETAILS
The SN75DP130 offers an AUX source channel (AUX_SRC), AUX sink channel (AUX_SNK), a selectable DDC
interface (SDA_DDC/SCL_DDC) for TMDS mode, and a local I2C control interface (SCL_CTL / SDA_CTL). Upon
power-up, the SN75DP130 enables the connection between the AUX_SNK to the appropriate source interface
based on CAD_SNK. Table 4 describes the switching logic, including the programmability through the local I2C
interface.
Note that the DDC interface incorporates 60kΩ pull-up resistors on SDA_DDC and SCL_DDC which are turned
on when CAD_SNK is high (TMDS mode) but turned off when CAD_SNK is low (DP mode).
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Table 4. AUX and DDC Interface Configurations
HPD_SNK
I2C
REGISTER
BIT 04.0
I2C
REGISTER
BIT 04.1
CAD_SNK
AUX_SNK
AUX_SRC
DDC
AUX
MONITOR
0
X
X
X
OFF
OFF
OFF
inactive
0
ON
ON
OFF
active
1
ON
OFF
ON
inactive
0
OFF
ON
OFF
active
DP sink detected; AUX_SNK disconnected
from AUX_SRC; AUX_SNK monitors AUX
training
1
ON
ON
OFF
inactive
TMDS cable adapter detected; AUX_SNK
connects to AUX_SRC and can be used to
short AC coupling caps
0
(default; works
for Intel,
NVIDIA, and
AMD)
0
(default)
1
(NVIDIA, AMD
special mode)
1
0
0
ON
1
ON
1
no sink detected; low power mode
DP sink detected; AUX_SNK connects to
AUX_SRC
TMDS cable adapter detected; DDC
connects to AUX_SNK
active
DP sink detected; AUX_SNK connects to
AUX_SRC
inactive
TMDS cable adapter detected; AUX_SRC
connects to AUX_SNK
OFF
1
COMMENT
undetermined
mode not recommended
MAIN LINK EQ CONFIGURATION DETAILS
The EQ input stage is self-configuring based on Link Training. A variety of EQ settings are available through
external pin configuration to accommodate for different PCB loss and GPU settings, and the I2C interface may be
utilized to fully customize EQ configuration lane-by-lane beyond the input pin configurability options, as described
in Table 5.
Table 5. Main Link EQ Configurations
EQ_I2C_ENABLE
(reg 05.7)
ADDR_EQ
VIL
CAD_SNK (1)
VIL = DP
VIH = TMDS
VIL
LINK
TRAINING
ON/OFF
(reg 04.2)
LINK TRAINING AEQ(Lx) (2)
LANE 0 to 2
1 (default)
AEQ(L0) = 8dB at 2.7GHz
AEQ(L1) = 6dB at 2.7GHz
AEQ(L2) = 3.5dB at 2.7GHz
AEQ(L3) = 0dB at 2.7GHz
0
VIH
0 (default)
VIM
VIL
VIH
VIH
VIL
x
1
0
x
1
0
VIH
x
1
1
x
VIH
20
AEQ(Lx) = 8dB at 2.7GHz
AEQ(Lx) = 8dB at 2.7GHz
AEQ(L0) = 15dB at 2.7GHz
AEQ(L1) = 13dB at 2.7GHz
AEQ(L2) = 10dB at 2.7GHz
AEQ(L3) = 6dB at 2.7GHz
AEQ(Lx) = 13dB at 2.7GHz
same as Lane 0 to 2
3dB at 1.35GHz
TMDS mode; fixed EQ
DP mode; fixed EQ
same as Lane 0 to 2
DP mode; fixed EQ
DP mode; fixed EQ
3dB at 1.35GHz
TMDS mode; fixed EQ
same as Lane 0 to 2
automatic high-range EQ gain
based on link training; DP
mode
3dB at 1.35GHz
TMDS mode; fixed EQ
DP mode; fixed EQ
same as Lane 0 to 2
AEQ(L1) = 6dB at 2.7GHz
AEQ(L1) I2C programmable
x
DESCRIPTION
automatic low-range EQ gain
based on link training; DP
mode
AEQ(Lx) = 0dB at 2.7GHz
AEQ(Lx) I2C programmable
VIL
0
(1)
(2)
AEQ(Lx) = 6dB at 2.7GHz
LINK TRAINING
AEQ(Lx) (2)
LANE 3
3dB at 1.35GHz
DP mode; EQ fully
programmable for each
training level; EQ disabled by
default
DP mode; EQ fully
programmable by AEQ(L1)
levels; default AEQ(L1) EQ
setting at 6dB At 2.7GHz
TMDS mode; fixed EQ
Setting CAD_TEST_MODE (Reg 17.0) forces the SN75DP130 into a TMDS test mode even if no external CAD signal is present
EQ setting is adjusted based on the output pre-emphasis level setting; the EQ setting is indifferent to the level of VOD.
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LINK TRAINING AND DPCD DESCRIPTION
The SN75DP130 monitors the auxiliary interface access to DisplayPort Configuration Data (DPCD) registers
during Link Training in DP mode to select the output voltage swing VOD, output pre-emphasis, and the EQ setting
of the Main Link. The AUX monitor for SN75DP130 supports Link Training in 1Mbps Manchester mode, and is
disabled during TMDS mode (CAD_SNK=VIH).
The AUX channel is further monitored for the DisplayPort D3 standby command.
The DPCD registers monitored by SN75DP130 are listed in Table 6. Bit fields not listed are reserved and values
written to reserved fields are ignored.
Table 6. DPCD Registers Utilized by the SN75DP130 AUX Monitor
ADDRESS
00100h
00101h
00103h
NAME
LINK_BW_SET
LANE_COUNT_SET
TRAINING_LANE0_SET
DESCRIPTION
Bits 7:0 = Link Bandwidth Setting
06h – 1.62Gbps per lane
0Ah – 2.7Gbps per lane (default)
14h – (or any other value) 5.4Gbps per lane
Bits 4:0 = Lane Count
0h – All lanes disabled (default)
1h – One lane enabled
2h – Two lanes enabled
4h – Four lanes enabled
Note: any other value is invalid and disables all Main Link output lanes
Bits 1:0 = Output Voltage VOD Level
00 – Voltage swing level 0 (default)
01 – Voltage swing level 1
10 – Voltage swing level 2
11 – Voltage swing level 3
Bits 4:3 = Pre-emphasis Level
00 – Pre-emphasis level 0 (default)
01 – Pre-emphasis level 1
10 – Pre-emphasis level 2
11 – Pre-emphasis level 3
Note: the following combinations are not allowed for bits [1:0]/[4:3]: 01/11, 10/10, 10/11,
11/01, 11/10, 11/11; setting to any of these invalid combinations disables all Main Link
lanes until the register value is changed back to a valid entry
00104h
TRAINING_LANE1_SET
Sets the VOD and pre-emphasis levels for lane 1
00105h
TRAINING_LANE2_SET
Sets the VOD and pre-emphasis levels for lane 2
00106h
TRAINING_LANE3_SET
Sets the VOD and pre-emphasis levels for lane 3
0010F
0110F
TRAINING_LANE0_1_SET2
TRAINING_LANE2_3_SET2
Bits 1:0 = Lane 0 Post Cursor 2
00 – IN0 expects post cursor2 level
01 – IN0 expects post cursor2 level
10 – IN0 expects post cursor2 level
11 – IN0 expects post cursor2 level
Bits 5:4 = Lane 1 Post Cursor 2
00 – IN1 expects post cursor2 level
01 – IN1 expects post cursor2 level
10 – IN1 expects post cursor2 level
11 – IN1 expects post cursor2 level
0; OUT0
1; OUT0
2; OUT0
3; OUT0
transmits at post cursor 2 level 0
remains at post cursor 2 level 0
remains at post cursor 2 level 0
remains at post cursor 2 level 0
0; OUT1
1; OUT1
2; OUT1
3; OUT1
transmits at post cursor 2 level 0
remains at post cursor 2 level 0
remains at post cursor 2 level 0
remains at post cursor 2 level 0
Bit definition identical to that of TRAINING_LANE_0_1_SET2 but for lanes 2 (IN2/OUT2)
and lane 3 (IN3/OUT3)
Bits 1:0 = Power Mode
01 – Normal mode (default)
10 – Power down mode; D3 Standby Mode
00600h
SET_POWER
The Main Link and all analog circuits are shut down and the AUX channel is monitored
during the D3 Standby Mode. The device exits D3 Standby Mode by access to this
register, when CAD_SNK goes high, or if HPD_SNK goes low for longer than tT(HPD),
which indicates that the DP sink was disconnected.
Note: setting the register to the invalid combination 0600h[1:0]=00 or 11 is ignored by the
device and the device remains in normal mode
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I2C INTERFACE OVERVIEW
The SN75DP130 I2C interface is enabled when EN and RSTN are input high. The SCL_CTL and SDA_CTL
terminals are used for I2C clock and I2C data respectively. The SN75DP130 I2C interface conforms to the
two-wire serial interface defined by the I2C Bus Specification, Version 2.1 (January 2000), and supports the
standard mode transfer up to 100 kbps.
The device address byte is the first byte received following the START condition from the master device. The 7
bit device address for SN75DP130 is factory preset to 01011xx with the two least significant bits being
determined by the ADDR_EQ 3-level control input. Table 7 clarifies the SN75DP130 target address.
Table 7. SN75DP130 I2C Target Address Description
BIT 7 (MSB)
0
BIT 6
1
Note: ADDR_EQ = LOW:
ADDR_EQ = VCC/2:
ADDR_EQ = HIGH:
SN75DP130 I2C TARGET ADDRESS
BIT 5
BIT 4
BIT 3
0
1
1
BIT 2
ADDR1
BIT 1
ADDR0
BIT 0 (W/R)
0/1
ADDR[1:0] = 00: W/R=58/59
ADDR[1:0] = 01: W/R=5A/5B;
ADDR[1:0] = 10: W/R=5C/5D
The following procedure is followed to write to the SN75DP130 I2C registers:
1. The master initiates a write operation by generating a start condition (S), followed by the SN75DP130 7-bit
address and a zero-value "W/R" bit to indicate a write cycle
2. The SN75DP130 acknowledges the address cycle
3. The master presents the sub-address (I2C register within SN75DP130) to be written, consisting of one byte
of data, MSB-first
4. The SN75DP130 acknowledges the sub-address cycle
5. The master presents the first byte of data to be written to the I2C register
6. The SN75DP130 acknowledges the byte transfer
7. The master may continue presenting additional bytes of data to be written, with each byte transfer completing
with an acknowledge from the SN75DP130
8. The master terminates the write operation by generating a stop condition (P)
The following procedure is followed to read the SN75DP130 I2C registers:
1. The master initiates a read operation by generating a start condition (S), followed by the SN75DP130 7-bit
address and a one-value "W/R" bit to indicate a read cycle
2. The SN75DP130 acknowledges the address cycle
3. The SN75DP130 transmit the contents of the memory registers MSB-first starting at register 00h.
4. The SN75DP130 will wait for either an acknowledge (ACK) or a not-acknowledge (NACK) from the master
after each byte transfer; the I2C master acknowledges reception of each data byte transfer
5. If an ACK is received, the SN75DP130 transmits the next byte of data
6. The master terminates the read operation by generating a stop condition (P)
Note that no sub-addressing is included for the read procedure, and reads start at register offset 00h and
continue byte by byte through the registers until the I2C master terminates the read operation.
Refer to Table 8 for SN75DP130 local I2C register descriptions. Reads from reserved fields not described return
zeros, and writes are ignored.
Table 8. SN75DP130 I2C Register Descriptions
ADDRESS
BIT(S)
1
AUTO_POWERDOWN_DISABLE
0 – The SN75DP130 automatically enters Standby mode based on HPD_SNK (default)
1 – The SN75DP130 will not automatically enter Standby mode
RW
0
FORCE_SHUTDOWN_MODE
0 – SN75DP130 is forced to Shutdown mode
1 – Shutdown mode is determined by EN input, normal operation (default)
RW
01h
(1)
22
ACCESS (1)
DESCRIPTION
RO = Read Only; RW = Read/Write; WO = Write Only (reads return undetermined values)
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Table 8. SN75DP130 I2C Register Descriptions (continued)
ACCESS (1)
ADDRESS
BIT(S)
02h
7:0
TI_TEST. This field defaults to zero value, and should not be modified.
RW
5:4
SQUELCH_SENSITIVITY. Main Link squelch sensitivity is selected by this field, and determines
the transitions to and from the Output Disable mode.
00 – Main Link IN0p/n squelch detection threshold set to 40mVpp
01 – Main Link IN0p/n squelch detection threshold set to 80mVpp (default)
10 – Main Link IN0p/n squelch detection threshold set to 160mVpp
11 – Main Link IN0p/n squelch detection threshold set to 250mVpp
RW
3
SQUELCH_ENABLE
0 – Main Link IN0p/n squelch detection enabled (default)
1 – Main Link IN0p/n squelch detection disabled
RW
3
TI_TEST. This field defaults to zero value, and should not be modified.
RW
RW
2
LINK_TRAINING_ENABLE
0 – Link Training is disabled. VOD and Pre-emphasis are configured through the I2C register
interface; the EQ is fixed when this bit is zero.
1 – Link Training is enabled (default)
03h
04h
1:0
7
6:4
07h
08h
09h
0Ah
0Bh
0Ch
AUX_DDC_MUX_CFG. See Table 3 for details on the programming of this field.
00 – AUX_SNK is switched to AUX_SRC for DDC source side based on CAD_SNK (default)
01 – AUX_SNK is switched to AUX_SRC based on the CAD_SNK input, and used to short circuit
AC coupling capacitors in the TMDS operating mode.
10 – AUX_SNK is switched to AUX_SRC side based on the HPD_SNK inptu, while the DDC
source interface remains disabled.
11 – Undefined operation
RW
EQ_I2C_ENABLE
0 – EQ settings controlled by device inputs only (default)
1 – EQ settings controlled by I2C register settings
RW
AEQ_L0_LANE0_SET. This field selects the EQ setting for Lane 0 when I2C_EQ_ENABLE is
set, Link Training is enabled, and the Link Training results in Level 0 pre-emphasis.
05h
06h
DESCRIPTION
000 – 0dB EQ gain (default)
001 – 1.5dB (HBR); 3.5dB (HBR2)
010 – 3dB (HBR); 6dB (HBR2)
011 – 4dB (HBR); 8dB (HBR2)
100 – 5dB (HBR);
101 – 6dB (HBR);
110 – 7dB (HBR);
111 – 9dB (HBR);
10dB
13dB
15dB
18dB
(HBR2)
(HBR2)
(HBR2)
(HBR2)
RW
2:0
AEQ_L1_LANE0_SET. Settings are the same as AEQ_L0_LANE0_SET
RW
6:4
AEQ_L2_LANE0_SET. Settings are the same as AEQ_L0_LANE0_SET
RW
2:0
AEQ_L3_LANE0_SET. Settings are the same as AEQ_L0_LANE0_SET
RW
6:4
AEQ_L0_LANE1_SET. Settings are the same as AEQ_L0_LANE0_SET
RW
2:0
AEQ_L1_LANE1_SET. Settings are the same as AEQ_L0_LANE0_SET
RW
6:4
AEQ_L2_LANE1_SET. Settings are the same as AEQ_L0_LANE0_SET
RW
2:0
AEQ_L3_LANE1_SET. Settings are the same as AEQ_L0_LANE0_SET
RW
6:4
AEQ_L0_LANE2_SET. Settings are the same as AEQ_L0_LANE0_SET
RW
2:0
AEQ_L1_LANE2_SET. Settings are the same as AEQ_L0_LANE0_SET
RW
6:4
AEQ_L2_LANE2_SET. Settings are the same as AEQ_L0_LANE0_SET
RW
2:0
AEQ_L3_LANE2_SET. Settings are the same as AEQ_L0_LANE0_SET
RW
6:4
AEQ_L0_LANE3_SET. Settings are the same as AEQ_L0_LANE0_SET
RW
2:0
AEQ_L1_LANE3_SET. Settings are the same as AEQ_L0_LANE0_SET
RW
6:4
AEQ_L2_LANE3_SET. Settings are the same as AEQ_L0_LANE0_SET
RW
2:0
AEQ_L3_LANE3_SET. Settings are the same as AEQ_L0_LANE0_SET
RW
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Table 8. SN75DP130 I2C Register Descriptions (continued)
ADDRESS
BIT(S)
DESCRIPTION
ACCESS (1)
4:3
BOOST. Controls the output pre-emphasis amplitude; allows to reduce or increase all
pre-emphasis settings by ~10%. Setting this field will impact VOD when pre-emphasis is disabled.
This setting also impacts the output in TMDS mode.
00 – Pre-emphasis reduced by ~10%; VOD reduced when pre-emphasis is disabled.
01 – Pre-emphasis nominal (default)
10 – Pre-emphasis increased by ~10%; VOD increased when pre-emphasis is disabled.
11 – Reserved
RW
TMDS_VOD. Sets the target output swing in TMDS mode.
0 – Low TMDS output swing (default)
1 – High TMDS output swing
RW
TMDS_VPRE. Controls the output pre-emphasis in TMDS mode
00 – No TMDS pre-emphasis (default)
01 – Low TMDS pre-emphasis
10 – High TMDS pre-emphasis
11 – Reserved
RW
3
HPD_TEST_MODE
0 – Normal HPD mode. HPD_SRC reflects the status of HPD_SNK (default)
1 – Test mode. HPD_SNK is pulled high internally, and the HPD_SRC output is driven high and
the Main Link is activated, depending on the squelch setting. This mode allows execution of
certain tests on SN75DP130 without a connected display sink.
RW
1
CAD_OUTPUT_INVERT
0 – CAD_SRC output high means TMDS cable adapter detected (default)
1 – CAD_SRC output low means TMDS cable adapter detected
RW
15h
2
1:0
17h
CAD_TEST_MODE
17h
0
0 – Normal CAD mode. CAD_SRC reflects the status of CAD_SNK, based on the value of
CAD_OUTPUT_INVERT (default)
RW
1 – Test mode. CAD_SRC indicates TMDS mode, depending on the value of
CAD_OUTPUT_INVERT; CAD_SNK input is ignored. This mode allows execution of certain tests
on SN75DP130 without a connected TMDS display sink.
18h – 1Ah
7:0
TI_TEST. These registers shall not be modified.
RW
2
7
I2C_SOFT_RESET. Writing a one to this register resets all I C registers to default values. Writing
a zero to this register has no effect. Reads from this register return zero.
6
DPCD_RESET. Writing a one to this register resets the DPCD register bits (corresponding to
DPCD addresses 103h – 106h, the AEQ_Lx_LANEy_SET bits). Writing a zero to this register has
no effect. Reads from this register return zero.
1Bh
1Ch
3:0
DPCD_ADDR_HIGH. This value maps to bits 19:16 of the 20-bit DPCD register address
accessed through the DPCD_DATA register.
RW
1Dh
7:0
DPCD_ADDR_MID. This value maps to bits 15:8 of the 20-bit DPCD register address accessed
through the DPCD_DATA register.
RW
1Eh
7:0
DPCD_ADDR_LOW. This value maps to bits 7:0 of the 20-bit DPCD register address accessed
through the DPCD_DATA register.
RW
1Fh
7:0
DPCD_DATA. This register contains the data to write into or read from the DPCD register
addressed by DPCD_ADDR_HIGH, DPCD_ADDR_MID, and DPCD_ADDR_LOW.
RW
7:1
DEV_ID_REV. This field identifies the device and revision.
0000000 – SN75DP130 Revision 0
RO
BIT_INVERT. The value read from this field is the inverse of that written.
Default read value is zero.
RW
20h
0
24
WO
21h
7:0
TI_TEST. These registers shall not be modified.
RW
22h – 27h
7:0
TI_TEST_RESERVED. These read only registers are reserved for test; writes are ignored.
RO
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PACKAGE OPTION ADDENDUM
www.ti.com
20-May-2011
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package
Drawing
Pins
Package Qty
Eco Plan
(2)
Lead/
Ball Finish
MSL Peak Temp
(3)
SN75DP130DSRGZR
ACTIVE
VQFN
RGZ
48
2500
Green (RoHS
& no Sb/Br)
CU NIPDAU Level-3-260C-168 HR
SN75DP130DSRGZT
ACTIVE
VQFN
RGZ
48
250
Green (RoHS
& no Sb/Br)
CU NIPDAU Level-3-260C-168 HR
SN75DP130SSRGZR
ACTIVE
VQFN
RGZ
48
2500
Green (RoHS
& no Sb/Br)
CU NIPDAU Level-3-260C-168 HR
SN75DP130SSRGZT
ACTIVE
VQFN
RGZ
48
250
Green (RoHS
& no Sb/Br)
CU NIPDAU Level-3-260C-168 HR
Samples
(Requires Login)
(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)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability
information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that
lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between
the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight
in homogeneous material)
(3)
MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
Addendum-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
18-May-2011
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
Package Package Pins
Type Drawing
SN75DP130DSRGZR
VQFN
RGZ
48
SPQ
Reel
Reel
A0
Diameter Width (mm)
(mm) W1 (mm)
B0
(mm)
K0
(mm)
P1
(mm)
W
Pin1
(mm) Quadrant
2500
330.0
16.4
7.3
7.3
1.5
12.0
16.0
Q2
SN75DP130DSRGZT
VQFN
RGZ
48
250
180.0
16.4
7.3
7.3
1.5
12.0
16.0
Q2
SN75DP130SSRGZR
VQFN
RGZ
48
2500
330.0
16.4
7.3
7.3
1.5
12.0
16.0
Q2
SN75DP130SSRGZT
VQFN
RGZ
48
250
180.0
16.4
7.3
7.3
1.5
12.0
16.0
Q2
Pack Materials-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
18-May-2011
*All dimensions are nominal
Device
Package Type
Package Drawing
Pins
SPQ
Length (mm)
Width (mm)
Height (mm)
SN75DP130DSRGZR
VQFN
RGZ
48
2500
346.0
346.0
33.0
SN75DP130DSRGZT
VQFN
RGZ
48
250
190.5
212.7
31.8
SN75DP130SSRGZR
VQFN
RGZ
48
2500
346.0
346.0
33.0
SN75DP130SSRGZT
VQFN
RGZ
48
250
190.5
212.7
31.8
Pack Materials-Page 2
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Following are URLs where you can obtain information on other Texas Instruments products and application solutions:
Products
Applications
Audio
www.ti.com/audio
Communications and Telecom www.ti.com/communications
Amplifiers
amplifier.ti.com
Computers and Peripherals
www.ti.com/computers
Data Converters
dataconverter.ti.com
Consumer Electronics
www.ti.com/consumer-apps
DLP® Products
www.dlp.com
Energy and Lighting
www.ti.com/energy
DSP
dsp.ti.com
Industrial
www.ti.com/industrial
Clocks and Timers
www.ti.com/clocks
Medical
www.ti.com/medical
Interface
interface.ti.com
Security
www.ti.com/security
Logic
logic.ti.com
Space, Avionics and Defense
www.ti.com/space-avionics-defense
Power Mgmt
power.ti.com
Transportation and
Automotive
www.ti.com/automotive
Microcontrollers
microcontroller.ti.com
Video and Imaging
www.ti.com/video
RFID
www.ti-rfid.com
Wireless
www.ti.com/wireless-apps
RF/IF and ZigBee® Solutions
www.ti.com/lprf
TI E2E Community Home Page
e2e.ti.com
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