DS90UH927Q 5MHz - 85MHz 24-bit Color FPD

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DS90UH927Q-Q1
SNLS433C – NOVEMBER 2012 – REVISED JANUARY 2015
DS90UH927Q-Q1 5-MHz to 85-MHz 24-Bit Color FPD-Link III Serializer with HDCP
1 Features
3 Description
•
The DS90UH927Q-Q1 serializer, in conjunction with
a
DS90UH928Q-Q1
or
DS90UH926Q-Q1
deserializer, provides a solution for secure distribution
of content-protected digital video within automotive
entertainment systems. This chipset translates a
FPD-Link video interface into a single-pair high-speed
serialized interface. The digital video data is protected
using the industry standard High-Bandwidth Digital
Content Protection (HDCP) copy protection scheme.
The FPD-Link III serial bus scheme supports full
duplex, high speed forward channel data
transmission
and
low-speed
back
channel
communication over a single differential link.
Consolidation of audio, video, and control data over a
single differential pair reduces the interconnect size
and weight, while also eliminating skew issues and
simplifying system design.
1
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Integrated HDCP Cipher Engine with On-Chip Key
Storage
Bidirectional Control Channel Interface with I2C
Compatible Serial Control Bus
Low EMI FPD-Link Video Input
Supports High Definition (720p) Digital Video
Format
5-MHz to 85-MHz PCLK Supported
RGB888 + VS, HS, DE and I2S Audio Supported
Up to 4 I2S Digital Audio Inputs for Surround
Sound Applications
4 Bidirectional GPIO Channels with 2 Dedicated
Pins
Single 3.3-V Supply with 1.8-V or 3.3-V
Compatible LVCMOS I/O Interface
AC-Coupled STP Interconnect up to 10 Meters
DC-Balanced & Scrambled Data with Embedded
Clock
Supports HDCP Repeater Application
Internal Pattern Generation
Low Power Modes Minimize Power Dissipation
Automotive Grade Product: AEC-Q100 Grade 2
Qualified
> 8-kV HBM and ISO 10605 ESD Rating
Backward Compatible Modes
2 Applications
•
•
The DS90UH927Q-Q1 serializer embeds the clock,
content protects the data payload, and level shifts the
signals to high-speed differential signaling. Up to 24
RGB data bits are serialized along with three video
control signals, and up to four I2S data inputs.
The FPD-Link data interface allows for easy
interfacing with data sources while also minimizing
EMI and bus width. EMI on the high-speed FPD-Link
III bus is minimized using low voltage differential
signaling, data scrambling and randomization, and
dc-balancing.
The HDCP cipher engine is implemented in both the
serializer and deserializer. HDCP keys are stored in
on-chip memory.
Automotive Displays for Navigation
Rear Seat Entertainment Systems
Device Information(1)
PART NUMBER
PACKAGE
BODY SIZE (NOM)
DS90UH927Q-Q1
WQFN (40)
6.00 mm x 6.00 mm
(1) For all available packages, see the orderable addendum at
the end of the data sheet.
Application Diagram
FPD-Link
FPD-Link
VDDIO
VDD33
(3.3V) (1.8V or 3.3V)
HOST
Graphics
Processor
FPD-Link Display Interface
VDD33
VDDIO
(1.8V or 3.3V) (3.3V)
RxIN3+/-
RxIN1+/RxIN0+/RxCLKIN+/-
TxOUT2+/-
DOUT+
RIN+
DOUT-
RIN100Q STP Cable
DS90UH927Q-Q1
Serializer
PDB
INTB
I2S 6
SCL
SDA
IDx
TxOUT3+/-
FPD-Link III
1 Pair/AC Coupled
RxIN2+/-
MAPSEL
LFMODE
REPEAT
BKWD
OEN
OSS_SEL
PDB
MAPSEL
LFMODE
BISTEN
MODE_SEL
DS90UH928Q-Q1
Deserializer
TxOUT1+/TxOUT0+/-
RGB Display
720p
24-bit Color Depth
TxCLKOUT+/INTB_IN
LOCK
PASS
6
I2S
MCLK
SCL
SDA
IDx
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.
DS90UH927Q-Q1
SNLS433C – NOVEMBER 2012 – 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
5
6.1
6.2
6.3
6.4
6.5
6.6
6.7
6.8
Absolute Maximum Ratings ...................................... 5
ESD Ratings.............................................................. 5
Recommended Operating Conditions....................... 6
Thermal Information .................................................. 6
DC Electrical Characteristics .................................... 7
AC Electrical Characteristics..................................... 9
DC and AC Serial Control Bus Characteristics....... 10
Recommended Timing Requirements for the Serial
Control Bus .............................................................. 10
6.9 Timing Requirements .............................................. 11
6.10 Typical Characteristics .......................................... 14
7
Detailed Description ............................................ 15
7.1 Overview ................................................................. 15
7.2
7.3
7.4
7.5
7.6
8
Functional Block Diagram .......................................
Feature Description.................................................
Device Functional Modes........................................
Programming...........................................................
Register Maps .........................................................
15
16
24
30
32
Application and Implementation ........................ 52
8.1 Application Information............................................ 52
8.2 Typical Application .................................................. 52
9 Power Supply Recommendations...................... 54
10 Layout................................................................... 55
10.1 Layout Guidelines ................................................. 55
10.2 Layout Example .................................................... 56
11 Device and Documentation Support ................. 60
11.1
11.2
11.3
11.4
Documentation Support ........................................
Trademarks ...........................................................
Electrostatic Discharge Caution ............................
Glossary ................................................................
60
60
60
60
12 Mechanical, Packaging, and Orderable
Information ........................................................... 60
4 Revision History
NOTE: Page numbers for previous revisions may differ from page numbers in the current version.
Changes from Revision B (June 2013) to Revision C
•
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
Changes from Revision A (November 2012) to Revision B
•
2
Page
Page
Changed layout of National data sheet to TI format............................................................................................................. 56
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SNLS433C – NOVEMBER 2012 – REVISED JANUARY 2015
5 Pin Configuration and Functions
RxIN0+
RxIN0-
CAPLVD12
INTB
VDD33_B
LFMODE
VDDIO
MAPSEL
BKWD
REPEAT
30
29
28
27
26
25
24
23
22
21
RTA Package
40-Pin WQFN With Exposed Thermal Pad
Top View
RxIN1-
31
20
CMF
RxIN1+
32
19
VDD33_A
RxIN2-
33
18
PDB
RxIN2+
34
17
DOUT+
16
DOUT-
15
RES1
RxCLKINRxCLKIN+
DS90UH927Q-Q1
35
TOP VIEW
36
DAP = GND
9
10
SCL
SDA
8
IDx
CAPL12
11
7
40
VDDIO
GPIO1
6
CAPP12
I2S_DD/GPI03
12
5
39
I2S_DC/GPI02
GPIO0
4
RES0
I2S_DB/GPIO_REG5
13
3
38
I2S_DA/GPIO_REG6
RxIN3+
2
CAPHS12
I2S_CLK/GPIO_REG8
14
1
37
I2S_WC/GPIO_REG7
RxIN3-
Pin Functions
PIN
NAME
I/O, TYPE
NO.
DESCRIPTION
FPD-LINK INPUT INTERFACE
RxCLKIN-
35
I, LVDS
Inverting LVDS Clock Input
The pair requires external 100-Ω differential termination for standard LVDS levels
RxCLKIN+
36
I, LVDS
True LVDS Clock Input
The pair requires external 100-Ω differential termination for standard LVDS levels
RxIN[3:0]-
37, 33, 31, 29
I, LVDS
Inverting LVDS Data Inputs
Each pair requires external 100-Ω differential termination for standard LVDS levels
RxIN[3:0]+
38, 34, 32, 30
I, LVDS
True LVDS Data Inputs
Each pair requires external 100-Ω differential termination for standard LVDS levels
LVCMOS PARALLEL INTERFACE
BKWD
GPIO[1:0]
22
40, 39
I, LVCMOS
w/ pull down
Backward Compatible Mode Select
BKWD = 0, interfacing to DS90UH926/8Q-Q1 (Default)
BKWD = 1, interfacing to DS90UR906/8Q-Q1, DS90UR916Q
Requires a 10-kΩ pullup if set HIGH
I/O, LVCMOS General Purpose I/O
w/ pull down See Table 1
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Pin Functions (continued)
PIN
I/O, TYPE
DESCRIPTION
NAME
NO.
I2S_DA
I2S_DB
I2S_DC
I2S_DD
3
4
5
6
I, LVCMOS
w/ pull down
Digital Audio Interface I2S Data Inputs
Shared with GPIO_REG6, GPIO_REG5, GPIO2, GPIO3
I2S_WC
I2S_CLK
1
2
I, LVCMOS
w/ pull down
Digital Audio Interface I2S Word Clock and I2S Bit Clock Inputs
Shared with GPIO_REG7 and GPIO_REG8
Table 3
LFMODE
25
I, LVCMOS
w/ pull down
Low Frequency Mode Select
LFMODE = 0, 15 MHz ≤ RxCLKIN ≤ 85 MHz (Default)
LFMODE = 1, 5 MHz ≤ RxCLKIN < 15 MHz
Requires a 10-kΩ pullup if set HIGH
MAPSEL
23
I, LVCMOS
w/ pull down
FPD-Link Input Map Select
MAPSEL = 0, LSBs on RxIN3± (Default)
MAPSEL = 1, MSBs on RxIN3±
See Figure 19 and Figure 20
Requires a 10-kΩ pullup if set HIGH
REPEAT
21
I, LVCMOS
w/ pull down
Repeater Mode Select
REPEAT = 0, Repeater Mode disabled (Default)
REPEAT = 1, Repeater Mode enabled
Requires a 10-kΩ pullup if set HIGH
OPTIONAL PARALLEL INTERFACE
GPIO[3:2]
GPIO_REG[
8:5]
6, 5
2, 1, 3, 4
I/O, LVCMOS General Purpose I/O
w/ pull down Shared with I2S_DD and I2S_DC
See Table 1
I/O, LVCMOS Register-Only General Purpose I/O
w/ pull down Shared with I2S_CLK, I2S_WC, I2S_DA, I2S_DB
See Table 2
CONTROL AND CONFIGURATION
I2C Address Select
External pullup to VDD33 is required under all conditions. DO NOT FLOAT.
Connect to external pullup to VDD33 and pulldown to GND to create a voltage divider.
See Figure 25 and Table 4
IDx
11
I, Analog
PDB
18
I, LVCMOS
w/ pulldown
SCL
9
I/O, LVCMOS I2C Clock Input / Output Interface
Open Drain Must have an external pullup to VDD33. DO NOT FLOAT.
Recommended pullup: 4.7 kΩ.
SDA
10
I/O, LVCMOS I2C Data Input / Output Interface
Open Drain Must have an external pullup to VDD33. DO NOT FLOAT.
Recommended pullup: 4.7 kΩ.
27
O, LVCMOS
Open Drain
Power-down Mode Input Pin
Must be driven or pulled up to VDD33. Refer to Power Supply Recommendations.
PDB = H, device is enabled (normal operation)
PDB = L, device is powered down.
When the device is in the powered down state, the Driver Outputs are both HIGH, the PLL is
shutdown, and IDD is minimized. Control Registers are RESET.
STATUS
INTB
HDCP Interrupt
INTB = H, normal
INTB = L, Interrupt request
Recommended pullup: 4.7 kΩ to VDDIO. DO NOT FLOAT.
FPD-LINK III SERIAL INTERFACE
CMF
20
Analog
DOUT-
16
I/O, LVDS
Inverting Output
The output must be AC-coupled with a 0.1-µF capacitor.
DOUT+
17
I/O, LVDS
True Output
The output must be AC-coupled with a 0.1-µF capacitor.
4
Common Mode Filter.
Connect 0.1 µF to GND (required)
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SNLS433C – NOVEMBER 2012 – REVISED JANUARY 2015
Pin Functions (continued)
PIN
NAME
NO.
I/O, TYPE
DESCRIPTION
POWER AND GROUND (1)
GND
VDD33_A
VDD33_B
VDDIO
DAP
Ground
Large metal contact at the bottom center of the device package Connect to the ground
plane (GND) with at least 9 vias.
19
26
Power
Power to on-chip regulator 3.0 V - 3.6 V. Each pin requires a 4.7 µF capacitor to GND
7, 24
Power
LVCMOS I/O Power 1.8 V ±5% OR 3.0 V - 3.6 V. Each pin requires 4.7 µF capacitor to GND
REGULATOR CAPACITOR
CAPP12
CAPHS12
CAPLVD12
12
14
28
CAP
Decoupling capacitor connection for on-chip regulator
Each requires a 4.7-µF decoupling capacitor to GND.
CAPL12
8
CAP
Decoupling capacitor connection for on-chip regulator
Requires two 4.7-µF decoupling capacitors to GND
15, 13
GND
Reserved
Connect to GND.
OTHER
RES[1:0]
(1)
The VDD (VDD33 and VDDIO) supply ramp should be faster than 1.5 ms with a monotonic rise.
6 Specifications
6.1 Absolute Maximum Ratings (1) (2) (3)
MIN
MAX
UNIT
Supply Voltage – VDD33 (4)
−0.3
4.0
V
Supply Voltage – VDDIO (4)
−0.3
4.0
V
−0.3
(VDDIO +
0.3)
V
−0.3
2.75
V
150
°C
150
°C
LVCMOS I/O Voltage
Serializer Output Voltage
Junction Temperature
−65
Storage Temperature, Tstg
(1)
(2)
(3)
(4)
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 Conditions. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
For soldering specifications, see product folder at www.ti.com and www.ti.com/lit/an/snoa549c/snoa549c.pdf.
If Military/Aerospace specified devices are required, please contact the Texas Instruments Sales Office/Distributors for availability and
specifications.
The DS90UH927Q-Q1 VDD33 and VDDIO voltages require a specific ramp rate during power up. The power supply ramp time must be
less than 1.5 ms with a monotonic rise
6.2 ESD Ratings
VALUE
V(ESD)
Electrostatic
discharge
Human body model (HBM), per AEC Q100-002 (1)
±8000
Charged device model (CDM), per AEC Q100-011
±1250
Machine model (MM)
±250
(IEC 61000-4-2, powered-up only)
RD = 330 Ω, CS = 150 pF
(ISO 10605)
RD = 330 Ω, CS = 150 pF/330 pF
RD = 2 kΩ, CS = 150 pF/330 pF
(1)
Air Discharge
(Pin 16 and 17)
±15000
Contact Discharge
(Pin 16 and 17)
±8000
Air Discharge
(Pin 16 and 17)
±15000
Contact Discharge
(Pin 16 and 17)
±8000
UNIT
V
V
AEC Q100-002 indicates HBM stressing is done in accordance with the ANSI/ESDA/JEDEC JS-001 specification.
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6.3 Recommended Operating Conditions
MIN
NOM
MAX
3
3.3
3.6
V
Connect VDDIO to 3.3 V and use 3.3-V IOs
3
3.3
3.6
V
Connect VDDIO to 1.8 V and use 1.8-V IOs
1.71
1.8
1.89
V
−40
+25
+105
Supply Voltage (VDD33)
LVCMOS Supply Voltage (VDDIO) (1)
Operating Free Air Temperature (TA)
PCLK Frequency
5
Supply Noise (2)
(1)
(2)
UNIT
°C
85
MHz
100
mVP-P
VDDIO < VDD33 + 0.3 V
Supply noise testing was done with minimum capacitors on the PCB. A sinusoidal signal is AC coupled to the VDD33 and VDDIOsupplies
with amplitude = 100 mVp-p measured at the device VDD33 and VDDIO pins. Bit error rate testing of input to the Ser and output of the
Des with 10 meter cable shows no error when the noise frequency on the Ser is less than 50 MHz. The Des on the other hand shows no
error when the noise frequency is less than 50 MHz.
6.4 Thermal Information
DS90UH927Q-Q1
THERMAL METRIC (1)
RTA (WQFN)
UNIT
40 PINS
RθJA
Junction-to-ambient thermal resistance
29.0
RθJC(top)
Junction-to-case (top) thermal resistance
14.4
RθJB
Junction-to-board thermal resistance
5.1
ψJT
Junction-to-top characterization parameter
0.2
ψJB
Junction-to-board characterization parameter
5.1
RθJC(bot)
Junction-to-case (bottom) thermal resistance
1.4
(1)
6
°C/W
For more information about traditional and new thermal metrics, see the IC Package Thermal Metrics application report, SPRA953.
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SNLS433C – NOVEMBER 2012 – REVISED JANUARY 2015
6.5 DC Electrical Characteristics
Over recommended operating supply and temperature ranges unless otherwise specified. (1) (2) (3)
PARAMETER
TEST CONDITIONS
PIN/FREQ.
MIN
TYP
MAX
UNIT
LVCMOS I/O
VIH
High Level Input Voltage
VDDIO = 3.0 V to 3.6 V (4)
2.0
VDDIO
V
VIL
Low Level Input Voltage
VDDIO = 3.0 V to 3.6 V (4)
GND
0.8
V
IIN
Input Current
VIN = 0 V or VDDIO = 3.0 V to
3.6 V (4)
+15
μA
2.0
VDDIO
V
VIH
High Level Input Voltage
0.65×
VDDIO
VDDIO
V
GND
0.8
V
VIL
Low Level Input Voltage
GND
0.35*
VDDIO
V
IIN
Input Current
PDB
−15
VDDIO = 3.0 V to 3.6 V
VOH
GPIO[1:0]
I2S_CLK
I2S_WC
VDDIO = 3.0 V to 3.6 V
I2S_D
[A,B,C,D]
VDDIO = 1.71 V to 1.89 V
LFMODE
VDDIO = 3.0 V MAPSEL
BKWD
to 3.6 V
VIN = 0 V or
REPEAT
VDDIO
VDDIO = 1.71
V to 1.89 V
VDDIO = 1.71 V to 1.89 V
IOH = −4 mA
High Level Output Voltage
IOL = +4 mA
VOL
Low Level Output Voltage
(5)
IOS
Output Short Circuit Current
IOZ
TRI-STATE® Output Current
VDDIO = 3.0 V
to 3.6 V
VDDIO = 1.71
V to 1.89 V
VDDIO = 3.0 V GPIO[3:0],
GPO_REG
to 3.6 V
[8:5]
VDDIO = 1.71
V to 1.89 V
±1
−15
±1
+15
μA
−15
±1
+15
μA
2.4
VDDIO
V
VDDIO 0.45
VDDIO
V
GND
0.4
V
GND
0.45
V
−55
VOUT = 0 V
−15
VOUT = 0 V or VDDIO, PDB = L,
mA
+15
μA
+100
mV
FPD-LINK LVDS RECEIVER
VTH
Threshold High Voltage
VTL
Threshold Low Voltage
|VID|
Differential Input Voltage Swing
VCM
Common Mode Voltage
IIN
Input Current
(1)
(2)
(3)
(4)
(5)
−100
VCM = 1.2 V
RxCLKIN±
RxIN[3:0]±
mV
200
0
−10
600
1.2
mV
2.4
V
+10
μA
The Electrical Characteristics tables list ensured specifications under the listed Recommended Operating Conditions except as
otherwise modified or specified by the Electrical Characteristics conditions and/or notes. Typical specifications are estimations only and
are not ensured.
Typical values represent most likely parametric norms at VDD33 = 3.3V, VDDIO = 1.8V or 3.3V, TA = 25°C, and at the Recommended
Operating Conditions at the time of product characterization and are not ensured.
Current into device pins is defined as positive. Current out of a device pin is defined as negative. Voltages are referenced to ground
except VOD and ΔVOD, which are differential voltages. Supply noise testing was done with minimum capacitors on the PCB. A sinusoidal
signal is AC coupled to the supply pins with amplitude = 100 mVp-p measured at the device VDD33 and VDDIO pins. Bit error rate testing
of input to the serializer and output of the deserializer with 10 meter cable shows no error when the noise frequency is less than 50
MHz.
PDB is specified to 3.3-V LVCMOS only and must be driven or pulled up to VDD33 or to VDDIO ≥ 3.0 V
IOS is not specified for an indefinite period of time. Do not hold in short circuit for more than 500 ms or part damage may result
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DC Electrical Characteristics (continued)
Over recommended operating supply and temperature ranges unless otherwise specified.(1)(2)(3)
PARAMETER
TEST CONDITIONS
PIN/FREQ.
MIN
TYP
MAX
UNIT
800
1000
1200 mVp-p
FPD-LINK III CML DRIVER
VODp-p
Differential Output Voltage
(DOUT+) – (DOUT-)
ΔVOD
Output Voltage Unbalance
VOS
Offset Voltage – Single-ended
RL = 100 Ω
1
2.50.25*
VODp-p
RL = 100 Ω
DOUT±
ΔVOS
Offset Voltage Unbalance
Single-ended
IOS
Output Short Circuit Current
RT
Internal Termination Resistance Differential
50
mV
V
(TYP)
1
50
DOUT+/- = 0V, PDB = L or H
mV
mA
100
120
Ω
VDD33= 3.6 V
135
160
mA
VDDIO = 3.6 V
100
500
μA
VDDIO = 1.89 V
200
600
VDD33= 3.6 V
133
mA
VDDIO = 3.6 V
100
μA
VDDIO = 1.89 V
100
VDD33 = 3.6 V
1.2
2.4
mA
VDDIO = 3.6 V
4
30
μA
VDDIO = 1.89 V
5
30
μA
VDD33 = 3.6 V
1
2.2
mA
VDDIO = 3.6 V
8
20
μA
VDDIO = 1.89 V
4
20
μA
80
SUPPLY CURRENT
IDD1
IDDIO1
IDD2
Checkerboard Pattern
Supply Current
RL = 100Ω,
PCLK = 85MHz
IDDIO2
Random Pattern
PRBS7
IDDS
IDDIOS
Supply Current — Remote Auto
Power Down
reg_0x01[7]=1, Back channel
Idle
IDDZ
IDDIOZ
8
Supply Current — Power Down
PDB = 0 V, All other LVCMOS
inputs = 0 V
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μA
μA
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SNLS433C – NOVEMBER 2012 – REVISED JANUARY 2015
6.6 AC Electrical Characteristics
Over recommended operating supply and temperature ranges unless otherwise specified. (1) (2) (3)
PARAMETER
TEST CONDITIONS
PIN/FREQ.
MIN
TYP
MAX
UNIT
0.25
0.5
0.75
UI
100
140
ps
100
140
ps
5
ms
FPD-LINK LVDS INPUT
tRSP
Receiver Strobe Position
See Figure 4
RxCLKIN±,
RXIN[3:0]±
FPD-LINK III CML I/O
tLHT
tHLT
CML Output Low-to-High Transition
Time
CML Output High-to-Low Transition
Time
tPLD
Serializer PLL Lock Time
tSD
Delay — Latency
tTJIT
tIJIT
DOUT+,
DOUT-
See Figure 3
See Figure 5,
(4)
PCLK = 5 MHz
to 85 MHz
See Figure 6
Output Total Jitter,
Bit Error Rate ≤1E-9, see Figure 7,
(5)
Checkerboard Pattern
PCLK=5 MHz, see Figure 8
Checkerboard Pattern
PCLK=85 MHz, see Figure 8
(6) (7) (8) (9)
f/40 < Jitter Freq < f/20, DES =
DS90UH926Q-Q1
Input Jitter Tolerance, Bit Error Rate
≤1E-9 (8) (10)
f/40 < Jitter Freq < f/20, DES =
DS90UH928Q-Q1
146*T
ns
0.17
0.2
UI
0.26
0.29
UI
RxCLKIN±
RxCLKIN±, f =
78 MHz
0.6
UI
0.5
UI
>4 /
PCLK or
>77
ns
2
I S RECEIVER
TI2S
I2S Clock Period, see Figure 10,
(7) (11)
THC
I2S Clock High Time, see Figure 10,
RxCLKIN± f=5 MHz to 85 MHz
I2S_CLK,
PCLK = 5 MHz
to 85 MHz
I2S_CLK
0.35
TI2S
I2S_CLK
0.35
TI2S
(11)
TLC
I2S Clock Low Time, see Figure 10,
(11)
2
tsr
I S Set-up Time
I2S_WC
I2S_D[A,B,C,D]
0.2
TI2S
thtr
I2S Hold Time
I2S_WC
I2S_D[A,B,C,D]
0.2
TI2S
OTHER I/O
tGPIO,FC
GPIO Pulse Width, Forward Channel
GPIO[3:0],
PCLK = 5 MHz
to 85 MHz
tGPIO,BC
GPIO Pulse Width, Back Channel
GPIO[3:0]
>2/PCLK
s
20
µs
(1)
The Electrical Characteristics tables list ensured specifications under the listed Recommended Operating Conditions except as
otherwise modified or specified by the Electrical Characteristics conditions and/or notes. Typical specifications are estimations only and
are not ensured.
(2) Typical values represent most likely parametric norms at VDD33 = 3.3V, VDDIO = 1.8V or 3.3V, TA = 25°C, and at the Recommended
Operating Conditions at the time of product characterization and are not ensured.
(3) Current into device pins is defined as positive. Current out of a device pin is defined as negative. Voltages are referenced to ground
except VOD and ΔVOD, which are differential voltages. Supply noise testing was done with minimum capacitors on the PCB. A sinusoidal
signal is AC coupled to the supply pins with amplitude = 100 mVp-p measured at the device VDD33 and VDDIO pins. Bit error rate testing
of input to the serializer and output of the deserializer with 10 meter cable shows no error when the noise frequency is less than 50
MHz.
(4) tPLD is the time required by the device to obtain lock when exiting power-down state with an active PCLK.
(5) Output jitter specs are dependent upon the input clock jitter at the SER.
(6) UI – Unit Interval is equivalent to one ideal serialized bit width. The UI scales with PCLK frequency.
(7) Specification is ensured by design and is not tested in production.
(8) Specification is ensured by characterization and is not tested in production.
(9) tTJIT (@BER of 1E-9) specifies the allowable jitter on RxCLKIN±.
(10) Jitter Frequency is specified in conjunction with DS90UH928Q-Q1 PLL bandwidth.
(11) I2S specifications for tLC and tHC pulses must each be greater than 2 PCLK periods to ensure sampling and supersedes the
0.35*TI2S_CLK requirement. tLC and tHC must be longer than the greater of either 0.35*TI2S_CLK or 2*PCLK.
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6.7 DC and AC Serial Control Bus Characteristics
Over 3.3-V supply and temperature ranges unless otherwise specified. (1) (2) (3)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
VIH
Input High Level
SDA and SCL
0.7*
VDDIO
VDD33
V
VIL
Input Low Level Voltage
SDA and SCL
GND
0.3*
VDD33
V
VHY
Input Hysteresis
>50
VOL
SDA or SCL, IOL = 1.25 mA
Iin
SDA or SCL, Vin = VDDIO or GND
Cin
(1)
(2)
(3)
Input Capacitance
mV
0
0.36
V
-10
+10
µA
SDA or SCL
<5
pF
The Electrical Characteristics tables list ensured specifications under the listed Recommended Operating Conditions except as
otherwise modified or specified by the Electrical Characteristics conditions and/or notes. Typical specifications are estimations only and
are not ensured.
Typical values represent most likely parametric norms at VDD33 = 3.3V, VDDIO = 1.8V or 3.3V, TA = 25°C, and at the Recommended
Operating Conditions at the time of product characterization and are not ensured.
Current into device pins is defined as positive. Current out of a device pin is defined as negative. Voltages are referenced to ground
except VOD and ΔVOD, which are differential voltages. Supply noise testing was done with minimum capacitors on the PCB. A sinusoidal
signal is AC coupled to the supply pins with amplitude = 100 mVp-p measured at the device VDD33 and VDDIO pins. Bit error rate testing
of input to the serializer and output of the deserializer with 10 meter cable shows no error when the noise frequency is less than 50
MHz.
6.8 Recommended Timing Requirements for the Serial Control Bus
Over 3.3-V supply and temperature ranges unless otherwise specified. (1) (2) (3)
MIN
fSCL
SCL Clock Frequency
tLOW
tHIGH
SCL Low Period
SCL High Period
MAX
UNIT
Standard Mode
0
NOM
100
kHz
Fast Mode
0
400
kHz
Standard Mode
4.7
µs
Fast Mode
1.3
µs
Standard Mode
4.0
µs
Fast Mode
0.6
µs
tHD;STA
Hold time for a start or a
repeated start condition, see
Figure 9
Standard Mode
4.0
µs
Fast Mode
0.6
µs
tSU:STA
Set Up time for a start or a
repeated start condition, see
Figure 9
Standard Mode
4.7
µs
Fast Mode
0.6
µs
tHD;DAT
tSU;DAT
tSU;STO
tBUF
(1)
(2)
(3)
10
Data Hold Time, see Figure 9
Standard Mode
Fast Mode
0
3.45
µs
0
0.9
µs
Standard Mode
250
Fast Mode
100
ns
Set Up Time for STOP
Condition, see Figure 9
Standard Mode
4.0
µs
Fast Mode
0.6
µs
Bus Free Time
Between STOP and START,
see Figure 9
Standard Mode
4.7
µs
Fast Mode
1.3
µs
Data Set Up Time, see Figure 9
ns
The Electrical Characteristics tables list ensured specifications under the listed Recommended Operating Conditions except as
otherwise modified or specified by the Electrical Characteristics conditions and/or notes. Typical specifications are estimations only and
are not ensured.
Typical values represent most likely parametric norms at VDD33 = 3.3V, VDDIO = 1.8V or 3.3V, TA = 25°C, and at the Recommended
Operating Conditions at the time of product characterization and are not ensured.
Current into device pins is defined as positive. Current out of a device pin is defined as negative. Voltages are referenced to ground
except VOD and ΔVOD, which are differential voltages. Supply noise testing was done with minimum capacitors on the PCB. A sinusoidal
signal is AC coupled to the supply pins with amplitude = 100 mVp-p measured at the device VDD33 and VDDIO pins. Bit error rate testing
of input to the serializer and output of the deserializer with 10 meter cable shows no error when the noise frequency is less than 50
MHz.
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Recommended Timing Requirements for the Serial Control Bus (continued)
Over 3.3-V supply and temperature ranges unless otherwise specified.(1)(2)(3)
MIN
tr
tf
NOM
MAX
UNIT
SCL & SDA Rise Time, see
Figure 9
Standard Mode
1000
ns
Fast Mode
300
ns
SCL & SDA Fall Time, see
Figure 9
Standard Mode
300
ns
Fast mode
300
ns
6.9 Timing Requirements
MIN
tR
SDA RiseTime – READ
tF
SDA Fall Time – READ
tSU;DAT
Set Up Time — READ
tHD;DAT
Hold Up Time — READ
tSP
Input Filter
NOM
MAX
UNIT
430
ns
20
ns
See Figure 9
560
ns
See Figure 9
615
ns
50
ns
SDA, RPU = 10 kΩ, Cb ≤ 400 pF, see Figure 9
RxIN[3:0]+
RxCLKIN+
+VOD/4
VTL
VCM
VTH
RxIN[3:0]RxClkIN-
-VOD/4
GND
RxCLKIN 18
RxIN[3:0]
I2S
GPIO[1:0]
PARALLEL-TO-SERIAL
Figure 1. FPD-Link DC VTH/VTL Definition
DOUT+
100 nF
Differential probe
D
100:
DOUT-
Input Impedance û 100 k:
CL ú 0.5 pf
BW û 3.5 GHz
100 nF
DOUT-
Single Ended
VOD
SCOPE
BW û 4GHz
VODVOD+
DOUT+
|
VOS
0V
VOD+
Differential
(DOUT+) - (DOUT-)
0V
VOD-
Figure 2. Serializer VOD DC Output
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+VOD
80%
(DOUT+) - (DOUT-)
0V
20%
-VOD
tLHT
tHLT
Figure 3. Output Transition Times
Previous Cycle
Next Cycle
RxCLKIN
(Differential)
1 UI
1 UI
1 UI
1 UI
1 UI
1 UI
1 UI
1 UI
1 UI
RxIN[3:0]
(Differential)
tRSP(min)
tRSP(typ)
tRSP(max)
Figure 4. FPD-Link Input Strobe Position
VDD
VDDIO
PDB
1/2 VDD33
RxCLKIN
tPLD
DOUT
(Diff.)
Driver On
Driver OFF, VOD = 0V
RxIN[3:0]
N-1
N
N+1
| |
Figure 5. Serializer Lock Time
N+2
|
tSD
RxCLKIN
0
1
2
0
1
2
0
1
2
START
STOP
BIT SYMBOL N BIT
0
1
2
| |
2
START
STOP
BIT SYMBOL N-1 BIT
| |
1
START
STOP
BIT SYMBOL N-2 BIT
| |
0
START
STOP
BIT SYMBOL N-3 BIT
| |
DOUT
| |
STOP
SYMBOL N-4 BIT
Figure 6. Latency Delay
12
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tTJIT
tTJIT
VOD (+)
DOUT
(Diff.)
EYE OPENING
0V
VOD (-)
tBIT (1 UI)
Figure 7. CML Serializer Output Jitter
+VOD
RxCLKIN
-VOD
+VOD
RxIN3
-VOD
+VOD
RxIN2
-VOD
+VOD
RxIN1
-VOD
+VOD
RxIN0
-VOD
Cycle N+1
Cycle N
Figure 8. Checkerboard Data Pattern
SDA
tf
tHD;STA
tLOW
tr
tf
tr
tBUF
tSP
SCL
tSU;STA
tHD;STA
tHIGH
tHD;DAT
START
tSU;STO
tSU;DAT
STOP
REPEATED
START
START
Figure 9. Serial Control Bus Timing Diagram
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T
tLC
tHC
VIH
I2S_CLK
VIL
tsr
thr
I2S_WC
I2S_D[A,B,C,D]
Figure 10. I2S Timing Diagram
6.10 Typical Characteristics
Input to Serializer
Output at Deserializer
Figure 11. Serializer Eye with 78-MHz Input Clock
14
Figure 12. 78-MHz Clock at Serializer and Deserializer
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7 Detailed Description
7.1 Overview
The DS90UH927Q-Q1 converts a FPD-Link interface (4 LVDS data channels + 1 LVDS Clock) to a FPD-Link III
interface. This device transmits a 35-bit symbol over a single serial pair operating at up to a 2.975-Gbps line rate.
The serial stream contains an embedded clock, video control signals, RGB video data, and audio data. The
payload is DC-balanced to enhance signal quality and support AC coupling.
The DS90UH927Q-Q1 applies encryption to the video data using a High-Bandwidth Digital Content Protection
(HDCP) Cipher, and transmits the encrypted data out through the FPD-Link III interface. Audio encryption is
supported. On chip non-volatile memory stores the HDCP keys. All key exchanges are conducted over the FPDLink III bidirectional control interface.
The DS90UH927Q-Q1 serializer is intended for use with a DS90UH928Q-Q1 or DS90UH926Q-Q1 deserializer,
but is also backward compatible with DS90UR906Q, DS90UR908Q, DS90UR910Q, and DS90UR916Q FPD-Link
II deserializers.
The DS90UH927Q-Q1 serializer and DS90UH928Q-Q1 or DS90UH926Q-Q1 deserializer incorporate an I2C
compatible interface. The I2C compatible interface allows programming of serializer or deserializer devices from a
local host controller. In addition, the devices incorporate a bidirectional control channel (BCC) that allows
communication between serializer/deserializer as well as remote I2C slave devices.
The bidirectional control channel (BCC) is implemented via embedded signaling in the high-speed forward
channel (serializer to deserializer) combined with lower speed signaling in the reverse channel (deserializer to
serializer). Through this interface, the BCC provides a mechanism to bridge I2C transactions across the serial link
from one I2C bus to another. The implementation allows for arbitration with other I2C compatible masters at either
side of the serial link.
7.2 Functional Block Diagram
RxIN1+/RxIN0+/RxCLKIN+/I2S / GPIO
DC Balance Encoder
RxIN2+/-
HDCP Cipher
Serial to Parallel
RxIN3+/-
Parallel to Serial
REGULATOR
CMF
DOUT+
DOUT-
8
LFMODE
MAPSEL
BKWD
REPEAT
PDB
INTB
PLL
Timing and
Control
SDA
SCL
IDx
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7.3 Feature Description
7.3.1 High-Speed Forward Channel Data Transfer
The High-Speed Forward Channel is composed of a 35-bit frame containing RGB data, sync signals, HDCP, I2C,
and I2S audio transmitted from Serializer to Deserializer. Figure 13 illustrates the serial stream generated per
PCLK cycle into RxCLKIN±. This data payload is optimized for signal transmission over an AC coupled link. Data
is randomized, DC-balanced and scrambled.
C0
C1
Figure 13. FPD-Link III Serial Stream
The device supports pixel clock ranges of 5 MHz to 15 MHz (LFMODE=1) and 15 MHz to 85 MHz (LFMODE=0).
This corresponds to an application payload rate range of 155 Mbps to 2.635 Gbps, with an actual line rate range
of 525 Mbps to 2.975 Gbps.
7.3.2 Low-Speed Back Channel Data Transfer
The Low-Speed Back Channel of the DS90UH927Q-Q1 provides bidirectional communication between the
display and host processor. Data is transferred simultaneously over the same physical link as the high-speed
forward channel data. The back channel transports I2C, HDCP, CRC, and 4 bits of standard GPIO information
with a 10 Mbps line rate.
7.3.3 Common Mode Filter Pin (CMF)
The serializer provides access to the center tap of the internal CML termination. A 0.1-μF capacitor must be
connected from this pin to GND for additional common-mode filtering of the differential pair (Figure 29). This
increases noise rejection capability in high-noise environments.
7.3.4 Video Control Signals
The video control signal bits embedded in the high-speed FPD-Link LVDS are subject to certain limitations
relative to the video pixel clock period (PCLK). By default, the DS90UH927Q-Q1 applies a minimum pulse width
filter on these signals to help eliminate spurious transitions.
Normal Mode Control Signals (VS, HS, DE) have the following restrictions:
• Horizontal Sync (HS): The video control signal pulse width must be 3 PCLKs or longer when the Control
Signal Filter (register bit 0x03[4]) is enabled (default). Disabling the Control Signal Filter removes this
restriction (minimum is 1 PCLK). See Table 5. HS can have at most two transitions per 130 PCLKs.
• Vertical Sync (VS): The video control signal pulse is limited to 1 transition per 130 PCLKs. Thus, the minimum
pulse width is 130 PCLKs.
• Data Enable Input (DE): The video control signal pulse width must be 3 PCLKs or longer when the Control
Signal Filter (register bit 0x03[4]) is enabled (default). Disabling the Control Signal Filter removes this
restriction (minimum is 1 PCLK). See Table 5. DE can have at most two transitions per 130 PCLKs.
7.3.5 EMI Reduction Features
7.3.5.1 LVCMOS VDDIO Option
The 1.8-V or 3.3-V LVCMOS inputs and outputs are powered from separate VDDIO supply pins to offer
compatibility with external system interface signals. Note: When configuring the VDDIO power supplies, all the
single-ended control input pins for device need to scale together with the same operating VDDIO levels. If VDDIO is
selected to operate in the 3.0 V to 3.6 V range, VDDIO must be operated within 300 mV of VDD33.
7.3.6 Built-In Self Test (BIST)
An optional At-Speed Built-In Self Test (BIST) feature supports testing of the high speed serial link and the lowspeed back channel without external data connections. This is useful in the prototype stage, equipment
production, in-system test, and system diagnostics.
16
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Feature Description (continued)
7.3.6.1 BIST Configuration and Status
The BIST mode is enabled at the deserializer by pin (BISTEN) or BIST configuration register. The test may
select either an external PCLK or the 33 MHz internal Oscillator clock (OSC) frequency. In the absence of PCLK,
the user can select the internal OSC frequency at the deserializer through the BISTC pin or BIST configuration
register.
When BIST is activated at the deserializer, a BIST enable signal is sent to the serializer through the Back
Channel. The serializer outputs a test pattern and drives the link at speed. The deserializer detects the test
pattern and monitors it for errors. The deserializer PASS output pin toggles to flag each frame received
containing one or more errors. The serializer also tracks errors indicated by the CRC fields in each back channel
frame.
The BIST status can be monitored real time on the deserializer PASS pin, with each detected error resulting in a
half pixel clock period toggled LOW. After BIST is deactivated, the result of the last test is held on the PASS
output until reset (new BIST or Power Down). A high on PASS indicates NO ERRORS were detected. A Low on
PASS indicates one or more errors were detected. The duration of the test is controlled by the pulse width
applied to the deserializer BISTEN pin. LOCK status is valid throughout the entire duration of BIST.
See Figure 14 for the BIST mode flow diagram.
Sample BIST Sequence
Step 1: For the DS90UH927Q-Q1 paired with a FPD-Link III Deserializer, BIST Mode is enabled via the BISTEN
pin of Deserializer. The desired clock source is selected through the deserializer BISTC pin.
Step 2: The DS90UH927Q-Q1 serializer is awakened through the back channel if it is not already on. An allzeros pattern is balanced, scrambled, randomized, and sent through the FPD-Link III interface to the deserializer.
Once the serializer and the deserializer are in BIST mode and the deserializer acquires Lock, the PASS pin of
the deserializer goes high and BIST starts checking the data stream. If an error in the payload (1 to 35) is
detected, the PASS pin will switch low for one half of the clock period. During the BIST, the PASS output can be
monitored and counted to determine the payload error rate.
Step 3: To Stop the BIST mode, the deserializer BISTEN pin is set Low. The deserializer stops checking the
data. The final test result is held on the PASS pin. If the test ran error free, the PASS output will remain HIGH. If
there one or more errors were detected, the PASS output will output constant LOW. The PASS output state is
held until a new BIST is run, the device is RESET, or the device is powered down. BIST duration is usercontrolled and may be of any length.
The link returns to normal operation after the deserializer BISTEN pin is low. Figure 15 shows the waveform
diagram of a typical BIST for two cases. Case 1 is error free, and Case 2 shows one with multiple errors. In most
cases it is difficult to generate errors due to the robustness of the link (differential data transmission, and so
forth), thus they may be introduced by greatly extending the cable length, faulting the interconnect medium, or
reducing signal condition enhancements (Rx Equalization).
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Feature Description (continued)
Normal
Step 1: DES in BIST
BIST
Wait
Step 2: Wait, SER in BIST
BIST
start
Step 3: DES in Normal
Mode - check PASS
BIST
stop
Step 4: DES/SER in Normal
Figure 14. BIST Mode Flow Diagram
7.3.7 Forward Channel and Back Channel Error Checking
While in BIST mode, the serializer stops sampling the FPD-Link input pins and switches over to an internal all
zeroes pattern. The internal all-zeroes pattern goes through scrambler, DC-balancing, and so forth, and is
transmitted over the serial link to the deserializer. The deserializer, on locking to the serial stream, compares the
recovered serial stream with all-zeroes and records any errors in status registers. Errors are also dynamically
reported on the PASS pin of the deserializer.
The back-channel data is checked for CRC errors once the serializer locks onto the back-channel serial stream,
as indicated by link detect status (register bit 0x0C[0] - Table 5). CRC errors are recorded in an 8-bit register in
the serializer. The register is cleared when the serializer enters the BIST mode. As soon as the serializer enters
BIST mode, the functional mode CRC register starts recording any back channel CRC errors. The BIST mode
CRC error register is active in BIST mode only and keeps the record of the last BIST run until cleared or the
serializer enters BIST mode again.
DES Outputs
BISTEN
(DES)
TxCLKOUT±
TxOUT[3:0]±
Case 1 - Pass
DATA
(internal)
PASS
Prior Result
PASS
PASS
X
X
X
FAIL
Prior Result
Normal
PRBS
Case 2 - Fail
X = bit error(s)
DATA
(internal)
BIST Test
BIST Duration
BIST
Result
Held
Normal
Figure 15. BIST Waveforms
18
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Feature Description (continued)
7.3.8 Internal Pattern Generation
The DS90UH927Q-Q1 serializer provides an internal pattern generation feature. It allows basic testing and
debugging of an integrated panel. The test patterns are simple and repetitive and allow for a quick visual
verification of panel operation. As long as the device is not in power down mode, the test pattern will be
displayed even if no input is applied. If no clock is received, the test pattern can be configured to use a
programmed oscillator frequency. For detailed information, refer to Application Note AN-2198 Exploring the
Internal Test Pattern Generation Feature of 720p (SNLA132).
7.3.8.1 Pattern Options
The DS90UH927Q-Q1 serializer pattern generator is capable of generating 17 default patterns for use in basic
testing and debugging of panels. Each pattern can be inverted using register bits (Table 5). The 17 default
patterns are listed as follows:
1. White/Black (default/inverted)
2. Black/White
3. Red/Cyan
4. Green/Magenta
5. Blue/Yellow
6. Horizontally Scaled Black to White/White to Black
7. Horizontally Scaled Black to Red/Cyan to White
8. Horizontally Scaled Black to Green/Magenta to White
9. Horizontally Scaled Black to Blue/Yellow to White
10. Vertically Scaled Black to White/White to Black
11. Vertically Scaled Black to Red/Cyan to White
12. Vertically Scaled Black to Green/Magenta to White
13. Vertically Scaled Black to Blue/Yellow to White
14. Custom Color (or its inversion) configured in PGRS
15. Black-White/White-Black Checkerboard (or custom checkerboard color, configured in PGCTL)
16. YCBR/RBCY VCOM pattern, orientation is configurable from PGCTL
17. Color Bars (White, Yellow, Cyan, Green, Magenta, Red, Blue, Black) – Note: not included in the autoscrolling feature
Additionally, the Pattern Generator incorporates one user-configurable full-screen 24-bit color, which is controlled
by the PGRS, PGGS, and PGBS registers. This is pattern #14. One of the pattern options is statically selected in
the PGCTL register when Auto-Scrolling is disabled. The PGTSC and PGTSO1-8 registers control the pattern
selection and order when Auto-Scrolling is enabled.
7.3.8.2 Color Modes
By default, the Pattern Generator operates in 24-bit color mode, where all bits of the Red, Green, and Blue
outputs are enabled. 18-bit color mode can be activated from the configuration registers (Table 5). In 18-bit
mode, the 6 most significant bits (bits 7-2) of the Red, Green, and Blue outputs are enabled; the 2 least
significant bits will be 0.
7.3.8.3 Video Timing Modes
The Pattern Generator has two video timing modes – external and internal. In external timing mode, the Pattern
Generator detects the video frame timing present on the DE and VS inputs. If Vertical Sync signaling is not
present on VS, the Pattern Generator determines Vertical Blank by detecting when the number of inactive pixel
clocks (DE = 0) exceeds twice the detected active line length. In internal timing mode, the Pattern Generator
uses custom video timing as configured in the control registers. The internal timing generation may also be
driven by an external clock. By default, external timing mode is enabled. Internal timing or Internal timing with
External Clock are enabled by the control registers (Table 5).
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Feature Description (continued)
7.3.8.4 External Timing
In external timing mode, the Pattern Generator passes the incoming DE, HS, and VS signals unmodified to the
video control outputs after a two pixel clock delay. It extracts the active frame dimensions from the incoming
signals in order to properly scale the brightness patterns. If the incoming video stream does not use the VS
signal, the Pattern Generator determines the Vertical Blank time by detecting a long period of pixel clocks without
DE asserted.
7.3.8.5 Pattern Inversion
The Pattern Generator also incorporates a global inversion control, located in the PGCFG register, which causes
the output pattern to be bitwise-inverted. For example, the full screen Red pattern becomes full-screen cyan, and
the Vertically Scaled Black to Green pattern becomes Vertically Scaled White to Magenta.
7.3.8.6 Auto Scrolling
The Pattern Generator supports an Auto-Scrolling mode, in which the output pattern cycles through a list of
enabled pattern types. A sequence of up to 16 patterns may be defined in the registers. The patterns may
appear in any order in the sequence and may also appear more than once.
7.3.9 Remote Auto Power Down Mode
The DS90UH927Q-Q1 serializer features a Remote Auto Power Down mode. This feature is enabled and
disabled through the register bit 0x01[7] (Table 5). When the back channel is not detected, either due to an idle
or powered-down deserializer, the serializer enters remote auto power down mode. Power dissipation of the
serializer is significantly reduced in this mode. The serializer automatically attempts to resume normal operation
upon detection of an active back channel from the deserializer. To complete the wake-up process and reactivate
forward channel operation, the remote power-down feature must be disabled by either a local I2C host, or by an
auto-ACK I2C transaction from a remote I2C host located at the deserializer. The Remote Auto Power Down
Sleep/Wake cycle is shown below in Figure 16:
Enable
Set reg_0x01[7]=1
Back Channel IDLE
Remote Auto Power
Down Enabled
Forward-channel
OFF
Normal Operation
Disable
Set reg_0x01[7]=0
Sleep
Back Channel ACTIVE
Figure 16. Remote Auto Power Down Sleep/Wake Cycle
To resume normal operation, the Remote Auto Power Down feature must be disabled in the device control
register. This may be accomplished from a local I2C controller by writing reg_0x01[7]=0 (Table 5). To disable
from a remote I2C controller located at the deserializer, perform the following procedure to complete the wake-up
process:
1. Power up remote deserializer (back channel must be active)
2. Enable I2C PASS-THROUGH ALL by setting deserializer register reg_0x05[7]=1
3. Enable I2C AUTO ACK by setting deserializer register reg_0x03[2]=1
4. Disable Remote Auto Power Down by setting serializer register reg_0x01[7]=0
5. Disable I2C AUTO ACK by setting deserializer register reg_0x03[2]=0
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Feature Description (continued)
6. Disable I2C PASS-THROUGH ALL by setting deserializer register reg_0x05[7]=0
7.3.10 Input RxCLKIN Loss Detect
The serializer can be programmed to enter a low power SLEEP state when the input clock (PCLK) is lost. A
clock loss condition is detected when PCLK drops below approximately 1MHz. When a PCLK is detected again,
the serializer will then lock to the incoming RxCLKIN±. Note: when RxCLKIN± is lost, the optional Serial Bus
Control Registers values are still retained. See (Table 5) for more information.
7.3.11 Serial Link Fault Detect
The DS90UH927Q-Q1 can detect fault conditions in the FPD-Link III interconnect. If a fault condition occurs, the
Link Detect Status is 0 (cable is not detected) on bit 0 of address 0x0C (Table 5). The DS90UH927Q-Q1 will
detect any of the following conditions:
1. Cable open
2. + to - short
3. + to GND short
4. - to GND short
5. + to battery short
6. - to battery short
7. Cable is linked incorrectly (DOUT+/DOUT- connections reversed)
NOTE
The device will detect any of the above conditions, but does not report specifically which
one has occurred.
7.3.12 INTERRUPT Pin (INTB)
1. On the DS90UH927Q-Q1 serializer, set register reg_0xC6[5] = 1 and 0xC6[0] = 1 (Table 5) to configure the
interrupt.
2. On the serializer, read from HDCP_ISR register 0xC7 to arm the interrupt for the first time.
3. When INTB_IN on the deserializer (DS90UH926Q-Q1 or DS90UH928Q-Q1) is set LOW, the INTB pin on the
serializer also pulls low, indicating an interrupt condition.
4. The external controller detects INTB = LOW and reads the HDCP_ISR register (Table 5) to determine the
interrupt source. Reading this register also clears and resets the interrupt.
7.3.13 General-Purpose I/O
7.3.13.1 GPIO[3:0]
In normal operation, GPIO[3:0] may be used as general purpose IOs in either forward channel (inputs) or back
channel (outputs) applications. GPIO modes may be configured from the registers (Table 5). GPIO[1:0] are
dedicated pins and GPIO[3:2] are shared with I2S_DC and I2S_DD respectively. Note: if the DS90UH927Q-Q1 is
paired with a DS90UH926Q-Q1 deserializer, the devices must be configured into 18-bit mode to allow usage of
GPIO pins on the DS90UH927 serializer. To enable 18-bit mode, set serializer register reg_0x12[2] = 1. 18-bit
mode will be auto-loaded into the deserializer from the serializer. See Table 1 for GPIO enable and configuration.
Table 1. GPIO Enable and Configuration
DESCRIPTION
DEVICE
FORWARD CHANNEL
BACK CHANNEL
GPIO3
DS90UH927Q-Q1
0x0F = 0x03
0x0F = 0x05
GPIO2
DS90UH926/8Q-Q1
0x1F = 0x05
0x1F = 0x03
DS90UH927Q-Q1
0x0E = 0x30
0x0E = 0x50
DS90UH926/8Q-Q1
0x1E = 0x50
0x1E = 0x30
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Feature Description (continued)
Table 1. GPIO Enable and Configuration (continued)
DESCRIPTION
DEVICE
FORWARD CHANNEL
BACK CHANNEL
GPIO1
DS90UH927Q-Q1
0x0E = 0x03
0x0E = 0x05
GPIO0
DS90UH926/8Q-Q1
0x1E = 0x05
0x1E = 0x03
DS90UH927Q-Q1
0x0D = 0x03
0x0D = 0x05
DS90UH926/8Q-Q1
0x1D = 0x05
0x1D = 0x03
The input value present on GPIO[3:0] may also be read from register, or configured to local output mode
(Table 5).
7.3.13.2 GPIO[8:5]
GPIO_REG[8:5] are register-only GPIOs and may be programmed as outputs or read as inputs through local
register bits only. Where applicable, these bits are shared with I2S pins and will override I2S input if enabled into
REG_GPIO mode. See Table 2 for GPIO enable and configuration.
Note: Local GPIO value may be configured and read either through local register access, or remote register
access through the Low-Speed Bidirectional Control Channel. Configuration and state of these pins are not
transported from serializer to deserializer as is the case for GPIO[3:0].
Table 2. GPIO_REG and GPIO Local Enable and Configuration
DESCRIPTION
REGISTER CONFIGURATION
GPIO_REG8
0x11 = 0x01
Output, L
0x11 = 0x09
Output, H
0x11 = 0x03
Input, Read: 0x1D[0]
0x10 = 0x01
Output, L
GPIO_REG7
GPIO_REG6
GPIO_REG5
GPIO3
GPIO2
GPIO1
GPIO0
22
FUNCTION
0x10 = 0x09
Output, H
0x10 = 0x03
Input, Read: 0x1C[7]
0x10 = 0x01
Output, L
0x10 = 0x09
Output, H
0x10 = 0x03
Input, Read: 0x1C[6]
0x0F = 0x01
Output, L
0x0F = 0x09
Output, H
0x0F = 0x03
Input, Read: 0x1C[5]
0x0F = 0x01
Output, L
0x0F = 0x09
Output, H
0x0F = 0x03
Input, Read: 0x1C[3]
0x0E = 0x01
Output, L
0x0E = 0x09
Output, H
0x0E = 0x03
Input, Read: 0x1C[2]
0x0E = 0x01
Output, L
0x0E = 0x09
Output, H
0x0E = 0x03
Input, Read: 0x1C[1]
0x0D = 0x01
Output, L
0x0D = 0x09
Output, H
0x0D = 0x03
Input, Read: 0x1C[0]
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7.3.14 I2S Audio Interface
The DS90UH927Q-Q1 serializer features six I2S input pins that, when paired with a DS90UH928Q-Q1
deserializer, supports surround sound audio applications. The bit clock (I2S_CLK) supports frequencies between
1 MHz and the smaller of <PCLK/2 or <13 MHz. Four I2S data inputs transport two channels of I2S-formatted
digital audio each, with each channel delineated by the word select (I2C_WC) input. I2S audio transport is not
available in Backwards Compatibility Mode (BKWD = 1).
DS90UH927Q-Q1
I2S
Transmitter
Bit Clock
Word Select
4
Data
I2S_CLK
I2S_WC
I2S_Dx
Figure 17. I2S Connection Diagram
I2S_WC
I2S_CLK
MSB
I2S_Dx
LSB MSB
LSB
Figure 18. I2S Frame Timing Diagram
When paired with a DS90UH926Q-Q1, the DS90UH927Q-Q1 I2S interface supports a single I2S data input
through I2S_DA (24-bit video mode), or two I2S data inputs through I2S_DA and I2S_DB (18-bit video mode).
Table 3 covers several common I2S sample rates:
Table 3. Audio Interface Frequencies
Sample Rate (kHz)
I2S Data Word Size (bits)
I2S CLK (MHz)
32
16
1.024
44.1
16
1.411
48
16
1.536
96
16
3.072
192
16
6.144
32
24
1.536
44.1
24
2.117
48
24
2.304
96
24
4.608
192
24
9.216
32
32
2.048
44.1
32
2.822
48
32
3.072
96
32
6.144
192
32
12.288
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7.3.14.1 I2S Transport Modes
By default, audio is packetized and transmitted during video blanking periods in dedicated Data Island Transport
frames. Data Island frames may be disabled from control registers if Forward Channel Frame Transport of I2S
data is desired. In this mode, only I2S_DA is transmitted to the DS90UH928Q-Q1 deserializer. If connected to a
DS90UH926Q-Q1 deserializer, I2S_DA and I2S_DB are transmitted. Surround Sound Mode, which transmits all
four I2S data inputs (I2S_D[A..D]), may only be operated in Data Island Transport mode. This mode is only
available when connected to a DS90UH928Q-Q1 deserializer.
7.3.14.2 I2S Repeater
I2S audio may be fanned-out and propagated in the repeater application. By default, data is propagated via Data
Island Transport on the FPD-Link interface during the video blanking periods. If frame transport is desired, then
the I2S pins should be connected from the deserializer to all serializers. Activating surround sound at the toplevel deserializer automatically configures downstream DS90UH927Q-Q1 serializers and DS90UH928Q-Q1
deserializers for surround sound transport utilizing Data Island Transport. If 4-channel operation utilizing I2S_DA
and I2S_DB only is desired, this mode must be explicitly set in each serializer and deserializer control register
throughout the repeater tree (Table 5).
A DS90UH927Q-Q1 serializer configured in repeater mode may also regenerate I2S audio from its I2S input pins
in lieu of Data Island frames. See the HDCP Repeater Connection Diagram (Figure 23) and the I2C Control
Registers (Table 5) for additional details.
7.3.15 Additional Features
Additional pattern generator features can be accessed through the Pattern Generator Indirect Register Map. It
consists of the Pattern Generator Indirect Address (PGIA reg_0x66 — Table 5) and the Pattern Generator
Indirect Data (PGID reg_0x67 — Table 5). See Application Note AN-2198 Exploring the Internal Test Pattern
Generation Feature of 720p (SNLA132).
7.4 Device Functional Modes
7.4.1 Power Down (PDB)
The Serializer has a PDB input pin to ENABLE or POWER DOWN the device. This pin may be controlled by an
external device, or through VDDIO, where VDDIO = 3.0 V to 3.6 V or VDD33. To save power, disable the link when
the display is not needed (PDB = LOW). Ensure that this pin is not driven HIGH before VDD33 and VDDIO have
reached final levels. When PDB is driven low, ensure that the pin is driven to 0 V for at least 1.5 ms before
releasing or driving high. In the case where PDB is pulled up to VDDIO = 3.0 V to 3.6 V or VDD33 directly, a 10-kΩ
pullup resistor and a >10-µF capacitor to ground are required (See Figure 29).
Toggling PDB low will POWER DOWN the device and RESET all control registers to default. During this time,
PDB must be held low for a minimum period of time. See AC Electrical Characteristics for more information.
7.4.2 Backward Compatible Mode
The DS90UH927Q-Q1 is also backward compatible to DS90UR906Q, DS90UR908Q FPD, and DS90UR916Q
FPD-Link II deserializers for PCLK frequencies ranging from 5 MHz to 65 MHz. It is also backward compatible
with the DS90UR910Q for PCLK frequencies ranging from 5 MHz to 75 MHz. The serializer transmits 28-bits of
data over a single serial FPD-Link II pair operating at a payload rate of 120 Mbps to 1.8 Gbps, corresponding to
a line rate of 140 Mbps to 2.1 Gbps. The Backward Compatibility configuration can be selected through the
BKWD pin or programmed through the configuration register (Table 5). The bidirectional control channel, HDCP,
bidirectional GPIOs, I2S, and interrupt (INTB) are not active in this mode. However, local I2C access to the
serializer is still available. Note: PCLK frequency range in this mode is 15 MHz to 75 MHz for LFMODE=0 and 5
MHZ to <15 MHz for LFMODE=1.
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Device Functional Modes (continued)
7.4.3 Low Frequency Optimization (LFMODE)
The LFMODE is set via register (Table 5) or LFMODE Pin. This mode optimizes device operation for lower input
data clock ranges supported by the serializer. If LFMODE is Low (LFMODE = 0, default), the RxCLKIN±
frequency is between 15 MHz and 85 MHz. If LFMODE is High (LFMODE = 1), the RxCLKIN± frequency is
between 5 MHz and <15 MHz. Note: when the device LFMODE is changed, a PDB reset is required. When
LFMODE is high (LFMODE=1), the line rate relative to the input data rate is multiplied by four. Thus, for the
operating range of 5 MHz to <15 MHz, the line rate is 700 Mbps to <2.1 Gbps with an effective data payload of
175 Mbps to 525 Mbps. Note: for Backwards Compatibility Mode (BKWD=1), the line rate relative to the input
data rate remains the same.
7.4.4 FPD-Link Input Frame and Color Bit Mapping Select
The DS90UH927Q-Q1 can be configured to accept 24-bit color (8-bit RGB) with 2 different mapping schemes:
LSBs on RxIN[3]±, shown in Figure 19, or MSBs on RxIN[3], shown in Figure 20. Each frame corresponds to a
single pixel clock (PCLK) cycle. The LVDS clock input to RxCLKIN± follows a 4:3 duty cycle scheme, with each
28-bit pixel frame starting with two LVDS bit clock periods high, three low, and ending with two high. The
mapping scheme is controlled by MAPSEL pin or by Register (Table 5).
RxCLKIN +/Previous cycle
Current cycle (PCLK Period)
RxIN3 +/-
DE
(bit 20)
RxIN2 +/-
R[1]
(bit 22)
R[0]
(bit 21)
B[6]
(bit 16)
B[5]
(bit 15)
B[4]
(bit 14)
G[6]
(bit 10)
G[5]
(bit 9)
G[4]
(bit 8)
G[3]
(bit 7)
R[5]
(bit 3)
R[4]
(bit 2)
R[3]
(bit 1)
R[2]
(bit 0)
B[1]
(bit 26)
B[0]
(bit 25)
G[1]
(bit 24)
VS
(bit 19)
HS
(bit 18)
B[7]
(bit 17)
G[7]
(bit 11)
R[6]
(bit 4)
RxIN1 +/-
B[3]
(bit 13)
B[2]
(bit 12)
RxIN0 +/-
G[2]
(bit 6)
R[7]
(bit 5)
G[0]
(bit 23)
Figure 19. FPD-Link Mapping: LSBs on RxIN3 (MAPSEL=L)
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Device Functional Modes (continued)
RxCLKIN +/Previous cycle
Current cycle (PCLK Period)
B[7]
(bit 26)
RxIN3 +/-
DE
(bit 20)
RxIN2 +/-
VS
(bit 19)
RxIN1 +/-
B[1]
(bit 13)
B[0]
(bit 12)
RxIN0 +/-
G[0]
(bit 6)
R[5]
(bit 5)
R[7]
(bit 22)
R[6]
(bit 21)
B[4]
(bit 16)
B[3]
(bit 15)
B[2]
(bit 14)
G[4]
(bit 10)
G[3]
(bit 9)
G[2]
(bit 8)
G[1]
(bit 7)
R[3]
(bit 3)
R[2]
(bit 2)
R[1]
(bit 1)
R[0]
(bit 0)
B[6]
(bit 25)
G[7]
(bit 24)
HS
(bit 18)
B[5]
(bit 17)
G[5]
(bit 11)
R[4]
(bit 4)
G[6]
(bit 23)
Figure 20. FPD-Link Mapping: MSBs on RxIN3 (MAPSEL=H)
7.4.5 HDCP
The Cipher function is implemented in the serializer per HDCP v1.3 specification. The DS90UH927Q-Q1
provides HDCP encryption of audiovisual content when connected to an HDCP capable FPD-Link III deserializer.
HDCP authentication and shared key generation is performed using the HDCP Control Channel which is
embedded in the forward and backward channels of the serial link. On-chip Non-Volatile Memory (NVM) is used
to store the HDCP keys. The confidential HDCP keys are loaded by TI during the manufacturing process and are
not accessible external to the device.
The DS90UH927Q-Q1 uses the Cipher engine to encrypt the data as per HDCP v1.3. The encrypted data is sent
through the FPD-Link III interface.
7.4.5.1 HDCP Repeater
The supported HDCP Repeater application provides a mechanism to extend HDCP transmission over multiple
links to multiple display devices. It authenticates all HDCP Receivers in the system and distributes protected
content to the HDCP Receivers using the encryption mechanisms provided in the HDCP specification.
7.4.5.2 HDCP I2S Audio Encryption
When HDCP is active, packetized Data Island Transport audio is also encrypted along with the video data per
HDCP v.1.3. I2S audio transmitted in Forward Channel Frame Transport mode is not encrypted. Depending on
the quality and specifications of the audiovisual source, HDCP encryption of digital audio may be required.
System designers should consult the specific HDCP specifications to determine if encryption of digital audio is
required by the specific application audiovisual source.
7.4.5.3 Repeater Configuration
In HDCP repeater application, this document refers to the DS90UH927Q-Q1 as the HDCP Transmitter (TX), and
refers to the DS90UH928Q-Q1 as the HDCP Receiver (RX). Figure 21 shows the maximum configuration
supported for HDCP Repeater implementations using the DS90UH925/7Q-Q1 (TX), and DS90UH926/8Q-Q1
(RX). Two levels of HDCP Repeaters are supported with a maximum of three HDCP Transmitters per HDCP
Receiver. To ensure parallel video interface compatibility, repeater nodes should feature either the
DS90UH926Q-Q1/DS90UH925Q (RX/TX) chipset or the DS90UH927Q-Q1/DS90UH928Q-Q1 (TX/RX) chipset.
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Device Functional Modes (continued)
1:3 Repeater
1:3 Repeater
TX
Source
TX
TX
RX
Display
TX
RX
Display
TX
RX
Display
TX
RX
Display
TX
RX
Display
TX
RX
Display
TX
RX
Display
TX
RX
Display
TX
RX
Display
RX
RX
TX
TX
1:3 Repeater
RX
1:3 Repeater
RX
Figure 21. HDCP Maximum Repeater Application
In a repeater application, the I2C interface at each TX and RX may be configured to transparently pass I2C
communications upstream or downstream to any I2C device within the system. This includes a mechanism for
assigning alternate IDs (Slave Aliases) to downstream devices in the case of duplicate addresses.
To support HDCP Repeater operation, the RX includes the ability to control the downstream authentication
process, assemble the KSV list for downstream HDCP Receivers, and pass the KSV list to the upstream HDCP
Transmitter. An I2C master within the RX communicates with the I2C slave within the TX. The TX handles
authenticating with a downstream HDCP Receiver and makes status available through the I2C interface. The RX
monitors the transmit port status for each TX and reads downstream KSV and KSV list values from the TX.
In addition to the I2C interface used to control the authentication process, the HDCP Repeater implementation
includes two other interfaces. The FPD-Link LVDS interface provides the unencrypted video data in 24-bit RGB
format and includes the DE/VS/HS control signals. In addition to providing the RGB video data, the LVDS
interface communicates control information and packetized audio data during video blanking intervals. A
separate I2S audio interface may optionally be used to send I2S audio data between the HDCP Receiver and
HDCP Transmitter in place of using the packetized audio. All audio and video data is decrypted at the output of
the HDCP Receiver and is re-encrypted by the HDCP Transmitter. Figure 22 provides more detailed block
diagram of a 1:2 HDCP repeater configuration.
If video data is output to a local display, White Balancing and Hi-FRC dithering functions should not be used as
they will block encrypted I2S audio.
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Device Functional Modes (continued)
HDCP Transmitter
TX
I2C
Master
I2C
downstream
Receiver
or
Repeater
I2C
Slave
upstream
Transmitter
FPD-Link
HDCP Receiver
(RX)
I2S Audio
HDCP Transmitter
TX
downstream
Receiver
or
Repeater
I2C
Slave
FPD-Link III interfaces
Figure 22. HDCP 1:2 Repeater Configuration
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Device Functional Modes (continued)
7.4.5.4 Repeater Connections
The HDCP Repeater requires the following connections between the HDCP Receiver and each HDCP
Transmitter Figure 23.
1. Video Data – Connect all FPD-Link data and clock pairs
2. I2C – Connect SCL and SDA signals. Both signals should be pulled up to VDD33 or VDDIO = 3.0 V to 3.6 V with
4.7-kΩ resistors.
3. Audio (optional) – Connect I2S_CLK, I2S_WC, and I2S_Dx signals.
4. IDx pin – Each HDCP Transmitter and Receiver must have a unique I2C address.
5. REPEAT pin — All HDCP Transmitters and Receivers must be set into Repeater Mode.
6. Interrupt pin – Connect DS90UH928Q-Q1 INTB_IN pin to DS90UH927Q-Q1 INTB pin. The signal must be
pulled up to VDDIO.
DS90UH928Q-Q1
DS90UH927Q-Q1
TxOUT0+
RxIN0+
TxOUT0-
RxIN0-
TxOUT1+
RxIN1+
TxOUT1-
RxIN1-
TxOUT2+
RxIN2+
TxOUT2-
RxIN2-
TxOUT3+
RxIN3+
TxOUT3-
RxIN3-
TxCLK+
RxCLK+
TxCLK-
RxCLK-
VDD33
MODE_SEL
VDD33
REPEAT
I2S_CLK
I2S_CLK
I2S_WC
I2S_WC
I2S_Dx
I2S_Dx
Optional
VDD33
VDD33
VDDIO
IDx
INTB
INTB_IN
IDx
VDD33
SDA
SDA
SCL
SCL
Figure 23. HDCP Repeater Connection Diagram
7.4.5.4.1 Repeater Fan-Out Electrical Requirements
Repeater applications requiring fan-out from one DS90UH928Q-Q1 deserializer to up to three DS90UH927Q-Q1
serializers requires special considerations for routing and termination of the FPD-Link differential traces.
Figure 24 details the requirements that must be met for each signal pair:
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Device Functional Modes (continued)
L3 < 60 mm
TX
(UH927)
RX
(UH928)
R1=100 TX
(UH927)
R2=100 L1 < 75 mm
L2 < 60 mm
TX
(UH927)
L3 < 60 mm
Figure 24. FPD-Link Fan-Out Electrical Requirements
7.5 Programming
7.5.1 Serial Control Bus
The DS90UH927Q-Q1 may also be configured by the use of an I2C compatible serial control bus. Multiple
devices may share the serial control bus (up to 10 device addresses supported). The device address is set via a
resistor divider (R1 and R2 — see Figure 25) connected to the IDx pin.
VDD33
VDD33
R1
VR2
4.7k
4.7k
IDx
R2
HOST
SER
SCL
SCL
SDA
SDA
To other
Devices
Figure 25. Serial Control Bus Connection
The serial control bus consists of two signals, SCL and SDA. SCL is a Serial Bus Clock Input. SDA is the Serial
Bus Data Input / Output signal. Both SCL and SDA signals require an external pullup resistor to VDD33 or VDDIO =
3.0 V to 3.6 V. For most applications, a 4.7-kΩ pullup resistor to VDD33 is recommended. However, the pullup
resistor value may be adjusted for capacitive loading and data rate requirements. The signals are either pulled
High, or driven Low.
The IDx pin configures the control interface to one of 10 possible device addresses. A pullup resistor and a
pulldown resistor may be used to set the appropriate voltage ratio between the IDx input pin (VR2) and VDD33,
each ratio corresponding to a specific device address. See Table 5.
30
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Programming (continued)
Table 4. Serial Control Bus Addresses for IDx
#
Ideal Ratio
VR2 / VDD33
Ideal VR2
(V)
Suggested Resistor Suggested Resistor
R1 kΩ (1% tol)
R2 kΩ (1% tol)
1
0
0
Open
2
0.306
1.011
3
0.350
1.154
4
0.393
5
Address 7'b
Address 8'b
40.2 or >10
0x0C
0x18
221
97.6
0x13
0x26
210
113
0x14
0x28
1.298
196
127
0x15
0x2A
0.440
1.452
182
143
0x16
0x2C
6
0.483
1.594
169
158
0x17
0x2E
7
0.529
1.745
147
165
0x18
0x30
8
0.572
1.887
143
191
0x19
0x32
9
0.618
2.040
121
196
0x1A
0x34
10
0.768
2.535
90.9
301
0x1B
0x36
The Serial Bus protocol is controlled by START, START-Repeated, and STOP phases. A START occurs when
SCL transitions Low while SDA is High. A STOP occurs when SDA transitions High while SCL is also HIGH. See
Figure 26.
SDA
SCL
S
P
START condition, or
START repeat condition
STOP condition
Figure 26. START and STOP Conditions
To communicate with a remote device, the host controller (master) sends the slave address and listens for a
response from the slave. This response is referred to as an acknowledge bit (ACK). If a slave on the bus is
addressed correctly, it Acknowledges (ACKs) the master by driving the SDA bus low. If the address doesn't
match a device's slave address, it Not-acknowledges (NACKs) the master by letting SDA be pulled High. ACKs
also occur on the bus when data is being transmitted. When the master is writing data, the slave ACKs after
every data byte is successfully received. When the master is reading data, the master ACKs after every data
byte is received to let the slave know it wants to receive another data byte. When the master wants to stop
reading, it NACKs after the last data byte and creates a stop condition on the bus. All communication on the bus
begins with either a Start condition or a Repeated Start condition. All communication on the bus ends with a Stop
condition. A READ is shown in Figure 27 and a WRITE is shown in Figure 28.
Register Address
Slave Address
S
A
2
A
1
A
0
0
Slave Address
a
c
k
a
c
k
A
2
S
A
1
A
0
Data
1
a
c
k
a
c
k
P
Figure 27. Serial Control Bus — READ
Register Address
Slave Address
S
A
2
A
1
A
0
0
a
c
k
Data
a
c
k
a
c
k
P
Figure 28. Serial Control Bus — WRITE
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The I2C Master located at the DS90UH927Q-Q1 serializer must support I2C clock stretching. For more
information on I2C interface requirements and throughput considerations, please refer to I2C Communication
Over FPD-Link III with Bidirectional Control Channel (SNLA131).
7.6 Register Maps
Table 5. Serial Control Bus Registers
ADD
(dec)
ADD
(hex)
Register Name
Bit
Register
Type
Default
(hex)
Function
Description
0
0x00
I2C Device ID
7:1
RW
IDx
Device ID
7–bit address of Serializer
Note: Read-only unless bit 0 is set
0
RW
ID Setting
I2C ID Setting
0: Device ID is from IDx pin
1: Register I2C Device ID overrides IDx pin
7
RW
Remote
Auto Power
Down
Remote Auto Power Down
0: Do not power down when no Bidirectional Control
Channel link is detected (default)
1: Enable power down when no Bidirectional Control
Channel link is detected
1
0x01
Reset
0x00
6:2
3
0x03
General
Configuration
Reserved.
1
RW
Digital
RESET1
Reset the entire digital block including registers
This bit is self-clearing.
0: Normal operation (default)
1: Reset
0
RW
Digital
RESET0
Reset the entire digital block except registers
This bit is self-clearing
0: Normal operation (default)
1: Reset
7
RW
Back
channel
CRC
Checker
Enable
Back Channel Check Enable
0: Disable
1: Enable (default)
0xD2
6
Reserved.
5
RW
I2C Remote
Write Auto
Acknowledg
e
Automatically Acknowledge I2C Remote Write When
enabled, I2C writes to the Deserializer (or any remote
I2C Slave, if I2C PASS ALL is enabled) are
immediately acknowledged without waiting for the
Deserializer to acknowledge the write. This allows
higher throughput on the I2C bus. Note: this mode will
prevent any NACK or read/write error indication from
a remote device from reaching the I2C master.
0: Disable (default)
1: Enable
4
RW
Filter
Enable
HS, VS, DE two clock filter When enabled, pulses
less than two full PCLK cycles on the DE, HS, and VS
inputs will be rejected
0: Filtering disable
1: Filtering enable (default)
3
RW
I2C Passthrough
I2C Pass-Through Mode
Read/Write transactions matching any entry in the
DeviceAlias registers will be passed through to the
remote deserializer I2C interface.
0: Pass-Through Disabled (default)
1: Pass-Through Enabled
2
32
Reserved
1
RW
PCLK Auto
Switch over to internal OSC in the absence of PCLK
0: Disable auto-switch
1: Enable auto-switch (default)
0
RW
TRFB
Reserved
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Register Maps (continued)
Table 5. Serial Control Bus Registers (continued)
ADD
(dec)
ADD
(hex)
Register Name
4
0x04
Mode Select
Bit
Register
Type
Default
(hex)
7
RW
0x80
Function
Description
Failsafe
State
Input Failsafe State
0: Failsafe to High
1: Failsafe to Low (default)
6
5
Reserved
RW
CRC Error
Reset
3
RW
BKWD
ModeOverri
de
Backward Compatible mode set by BKWD pin or
register
0: BC mode is set by BKWD pin (default)
1: BC mode is set by register bit
2
RW
BKWD
Backward compatibility mode, device to pair with
DS90UR906Q, DS90UR908Q, or DS90UR916Q
0: Normal HDCP device (default)
1: Compatible with 906/908/916
1
RW
LFMODE
Override
Frequency mode set by LFMODE pin or register
0: Frequency mode is set by LFMODE pin (default)
1: Frequency mode is set by register bit
0
RW
LFMODE
Frequency mode select
0: High frequency mode (15 MHz ≤ RxCLKIN ≤ 85
MHz) (default)
1: Low frequency mode (5 MHz ≤ RxCLKIN < 15
MHz)
4
5
0x05
I2C Control
Clear back channel CRC Error Counters
This bit is NOT self-clearing
0: Normal Operation (default)
1: Clear Counters
Reserved
7:5
0x00
Reserved
4:3
RW
SDA Output SDA output delay
Delay
Configures output delay on the SDA output. Setting
this value will increase output delay in units of 40 ns.
Nominal output delay values for SCL to SDA are:
00: 240 ns (default)
01: 280 ns
10: 320 ns
11: 360 ns
2
RW
Local Write
Disable
Disable Remote Writes to Local Registers
Setting this bit to a 1 will prevent remote writes to
local device registers from across the control channel.
This prevents writes to the Serializer registers from an
I2C master attached to the Deserializer. Setting this
bit does not affect remote access to I2C slaves at the
Serializer.
0: Enable (default)
1: Disable
1
RW
I2C Bus
Timer
Speedup
Speed up I2C Bus Watchdog Timer
0: Watchdog Timer expires after ~1 s (default)
1: Watchdog Timer expires after ~50 µs
0
RW
I2C Bus
timer
Disable
Disable I2C Bus Watchdog Timer
When the I2C Watchdog Timer may be used to detect
when the I2C bus is free or hung up following an
invalid termination of a transaction. If SDA is high and
no signaling occurs for approximately 1s, the I2C bus
will be assumed to be free. If SDA is low and no
signaling occurs, the device will attempt to clear the
bus by driving 9 clocks on SCL
0: Enable (default)
1: Disable
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Register Maps (continued)
Table 5. Serial Control Bus Registers (continued)
ADD
(dec)
ADD
(hex)
Register Name
Bit
Register
Type
Default
(hex)
6
0x06
DES ID
7:1
RW
0x00
DES Device 7-bit Deserializer Device ID
ID
Configures the I2C Slave ID of the remote
Deserializer. A value of 0 in this field disables I2C
access to the remote Deserializer. This field is
automatically configured by the Bidirectional Control
Channel once RX Lock has been detected. Software
may overwrite this value, but should also assert the
FREEZE DEVICE ID bit to prevent overwriting by the
Bidirectional Control Channel.
7
0x07
Slave ID 0
7:1
RW
0X00
Slave
Device ID 0
8
0x08
Slave Alias 0
7:1
RW
0x00
Slave
Device
Alias ID 0
10
0x0A
CRC Errors
7:0
R
0x00
CRC Error
LSB
Number of Back Channel CRC errors – 8 least
significant bits. Cleared by 0x04[5]
11
0x0B
7:0
R
0x00
CRC Error
MSB
Number of Back Channel CRC errors – 8 most
significant bits. Cleared by 0x04[5]
12
0x0C
Function
0
Reserved
0
34
7-bit Remote Slave Device ID 0
Configures the physical I2C address of the remote I2C
Slave device attached to the remote Deserializer. If an
I2C transaction is addressed to the Slave Device Alias
ID 0, the transaction will be remapped to this address
before passing the transaction across the Bidirectional
Control Channel to the Deserializer.
Reserved
0
General Status
Description
7-bit Remote Slave Device Alias ID 0 Configures the
decoder for detecting transactions designated for an
I2C Slave device attached to the remote Deserializer.
The transaction will be remapped to the address
specified in the Slave ID 0 register. A value of 0 in this
field disables access to the remote I2C Slave.
Reserved
7:4
0x00
Reserved
3
R
BIST CRC
Error
Back Channel CRC error during BIST communication
with Deserializer. This bit is cleared upon loss of link,
restart of BIST, or assertion of CRC ERROR RESET
in register 0x04.
0: No CRC errors detected during BIST (default)
1: CRC Errors detected during BIST
2
R
PCLK
Detect
Pixel Clock Status
0: Valid PCLK not detected (default)
1: Valid PCLK detected
1
R
DES Error
CRC error during BIST communication with
Deserializer. This bit is cleared upon loss of link or
assertion of 0x04[5]
0: No CRC errors detected (default)
1: CRC errors detected
0
R
LINK Detect LINK Detect Status
0: Cable link not detected (default)
1: Cable link detected
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Register Maps (continued)
Table 5. Serial Control Bus Registers (continued)
ADD
(dec)
ADD
(hex)
13
0x0D
14
0x0E
Register Name
Bit
Register
Type
Default
(hex)
GPIO0
Configuration
7:4
R
0x20
3
GPIO1 and
GPIO2
Configuration
Function
Description
Revision ID
Revision ID:
0010: Production Device
RW
GPIO0
Output
Value
Local GPIO Output Value This value is output on the
GPIO pin when the GPIO function is enabled, the
local GPIO direction is Output, and remote GPIO
control is disabled.
0: Output LOW (default)
1: Output HIGH
2
RW
GPIO0
Remote
Enable
Remote GPIO Control
0: Disable GPIO control from remote Deserializer
(default)
1: Enable GPIO control from remote Deserializer. The
GPIO pin will be an output, and the value is received
from the remote Deserializer.
1
RW
GPIO0
Direction
Local GPIO Direction
0: Output (default)
1: Input
0
RW
GPIO0
Enable
GPIO Function Enable
0: Enable normal operation (default)
1: Enable GPIO operation
7
RW
GPIO2
Output
Value
Local GPIO Output Value This value is output on the
GPIO pin when the GPIO function is enabled, the
local GPIO direction is Output, and remote GPIO
control is disabled.
0: Output LOW (default)
1: Output HIGH
6
RW
GPIO2
Remote
Enable
Remote GPIO Control
0: Disable GPIO control from remote Deserializer
(default)
1: Enable GPIO control from remote Deserializer. The
GPIO pin will be an output, and the value is received
from the remote Deserializer.
5
RW
GPIO2
Direction
Local GPIO Direction
0: Output (default)
1: Input
4
RW
GPIO2
Enable
GPIO Function Enable
0: Enable normal operation (default)
1: Enable GPIO operation
3
RW
GPIO1
Output
Value
Local GPIO Output Value This value is output on the
GPIO pin when the GPIO function is enabled, the
local GPIO direction is Output, and remote GPIO
control is disabled.
0: Output LOW (default)
1: Output HIGH
2
RW
GPIO1
Remote
Enable
Remote GPIO Control
0: Disable GPIO control from remote Deserializer
(default)
1: Enable GPIO control from remote Deserializer. The
GPIO pin will be an output, and the value is received
from the remote Deserializer.
1
RW
GPIO1
Direction
Local GPIO Direction
1: Input
0: Output
0
RW
GPIO1
Enable
GPIO function enable
1: Enable GPIO operation
0: Enable normal operation
0x00
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Register Maps (continued)
Table 5. Serial Control Bus Registers (continued)
ADD
(dec)
ADD
(hex)
15
0x0F
16
0x10
Register Name
Bit
GPIO3
Configuration
7:4
GPIO_REG5
and
GPIO_REG6
Configuration
Register
Type
Default
(hex)
Function
0x00
Reserved
3
RW
GPIO3
Output
Value
Local GPIO Output Value This value is output on the
GPIO pin when the GPIO function is enabled, the
local GPIO direction is Output, and remote GPIO
control is disabled.
0: Output LOW (default)
1: Output HIGH
2
RW
GPIO3
Remote
Enable
Remote GPIO Control
0: Disable GPIO control from remote Deserializer
(default)
1: Enable GPIO control from remote Deserializer. The
GPIO pin will be an output, and the value is received
from the remote Deserializer.
1
RW
GPIO3
Direction
Local GPIO Direction
0: Output (default)
1: Input
0
RW
GPIO3
Enable
GPIO Function Enable
0: Enable normal operation (default)
1: Enable GPIO operation
7
RW
GPIO_REG
6 Output
Value
Local GPIO Output Value This value is output on the
GPIO pin when the GPIO function is enabled, and the
local GPIO direction is Output.
0: Output LOW (default)
1: Output HIGH
0x00
6
Reserved
5
RW
GPIO_REG
6 Direction
Local GPIO Direction
0: Output (default)
1: Input
4
RW
GPIO_REG
6 Enable
GPIO Function Enable
0: Enable normal operation (default)
1: Enable GPIO operation
3
RW
GPIO_REG
5 Output
Value
Local GPIO Output Value This value is output on the
GPIO pin when the GPIO function is enabled, and the
local GPIO direction is Output.
0: Output LOW (default)
1: Output HIGH
1
RW
GPIO_REG
5 Direction
GPIO Function Enable
0: Enable normal operation (default)
1: Enable GPIO operation
0
RW
GPIO_REG
5 Enable
GPIO Function Enable
0: Enable normal operation (default)
1: Enable GPIO operation
2
36
Description
Reserved
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Register Maps (continued)
Table 5. Serial Control Bus Registers (continued)
ADD
(dec)
ADD
(hex)
17
0x11
Register Name
GPIO_REG7
and
GPIO_REG8
Configuration
Bit
Register
Type
Default
(hex)
7
RW
0x00
Function
Description
GPIO_REG
8 Output
Value
Local GPIO Output Value This value is output on the
GPIO pin when the GPIO function is enabled, and the
local GPIO direction is Output.
0: Output LOW (default)
1: Output HIGH
6
Reserved
5
RW
GPIO_REG
8 Direction
Local GPIO Direction
0: Output (default)
1: Input
4
RW
GPIO_REG
8 Enable
GPIO Function Enable
0: Enable normal operation (default)
1: Enable GPIO operation
3
RW
GPIO_REG
7 Output
Value
Local GPIO Output Value This value is output on the
GPIO pin when the GPIO function is enabled, and the
local GPIO direction is Output.
0: Output LOW (default)
1: Output HIGH
1
RW
GPIO_REG
7 Direction
Local GPIO Direction
0: Output (default)
1: Input
0
RW
GPO_REG
7 Enable
GPIO Function Enable
0: Enable normal operation (default)
1: Enable GPIO operation
2
18
0x12
Data Path
Control
Reserved
7
0x00
Reserved
6
RW
Pass RGB
Pass RGB on DE
Setting this bit causes RGB data to be sent
independent of DE in DS90UH927, which can be
used to allow DS90UH927 to interoperate with
DS90UB926, DS90UB928, and DS90UR906.
However, setting this bit prevents HDCP operation
and blocks packetized audio. This bit does not need
to be set in Backward Compatibility mode.
0: Normal operation (default)
1: Pass RGB independent of DE
5
RW
DE Polarity
This bit indicates the polarity of the DE (Data Enable)
signal.
0: DE is positive (active high, idle low) (default)
1: DE is inverted (active low, idle high)
4
RW
I2S
Repeater
Regen
Regenerate I2S Data From Repeater I2S Pins
0: Repeater pass through I2S from video pins (default)
1: Repeater regenerate I2S from I2S pins
3
RW
I2S Channel I2S Channel B Override
B Enable
0: Set I2S Channel B Disabled (default)
Override
1: Set I2S Channel B Enable from reg_12[0]
2
RW
18-bit Video Video Color Depth Mode
Select
0: Select 24-bit video mode (default)
1: Select 18-bit video mode
1
RW
I2S
Transport
Select
0
RW
I2S Channel I2S Channel B Enable
B Enable
0: I2S Channel B disabled (default)
1: Enable I2S Channel B
Select I2S Transport Mode
0: Enable I2S Data Island Transport (default)
1: Enable I2S Data Forward Channel Frame Transport
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Register Maps (continued)
Table 5. Serial Control Bus Registers (continued)
ADD
(dec)
ADD
(hex)
19
0x13
Register Name
Bit
Register
Type
Default
(hex)
General
Purpose Control
7
R
0x10
6
5
Function
Description
MAPSEL
Mode
Returns Map Select Mode (MAPSEL) pin status
RW
MAPSEL
Override
FPD-Link Map Select (MAPSEL) set by input pin or
register
0: Map Select is set by input pin (default)
1: Map Select is set by register bit 0x13[5]
RW
MAPSEL
Value
FPD-Link Map Select (MAPSEL) value when 0x13[6]
is set
0: LSBs on RxIN3± (default)
1: MSBs on RxIN3±
3
R
LFMODE
Status
Low Frequency Mode (LFMODE) pin status
0: 15 ≤ RxCLKIN ≤ 85 MHz (default)
1: 5 ≤ RxCLKIN < 15 MHz
2
R
REPEAT
Status
Repeater Mode (REPEAT) pin Status
0: Non-repeater (default)
1: Repeater
1
R
BKWD
Status
Backward Compatible Mode (BKWD) Status
0: Compatible to DS90UB926/8Q-Q1 (default)
1: Backward compatible to DS90UR906/8Q-Q1
0
R
I2S_DB
Status
I2S Channel B Mode (I2S_DB) Status
0: I2S_DB inactive (default)
1: I2S_DB active
4
20
22
38
0x14
0x16
BIST Control
BCC Watchdog
Control
Reserved
7:3
0x00
2:1
RW
0
R
7:1
RW
0
RW
0xFE
Reserved
OSC Clock
Source
Internal OSC clock select for Functional Mode or
BIST. Functional Mode when PCLK is not present and
0x03[1]=1.
00: 33-MHz Oscillator (default)
01: 33-MHz Oscillator
Clock Source in BIST mode
00: External Pixel Clock (default)
01: 33-MHz Oscillator
Note: In LFMODE=1, the internal oscillator is 12.5
MHz
BIST
Enable
BIST Control
0: Disabled (default)
1: Enabled
Timer Value The watchdog timer allows termination of a control
channel transaction if it fails to complete within a
programmed amount of time. This field sets the
Bidirectional Control Channel Watchdog Timeout
value in units of 2 milliseconds. This field should not
be set to 0.
Timer
Control
Disable BCC Watchdog Timer
0: Enable BCC Watchdog Timer operation (default)
1: Disable BCC Watchdog Timer operation
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Register Maps (continued)
Table 5. Serial Control Bus Registers (continued)
ADD
(dec)
ADD
(hex)
Register Name
23
0x17
I2C Control
Bit
Register
Type
Default
(hex)
7
RW
0x1E
6:4
RW
SDA Hold
Time
Internal SDA Hold Time
Configures the amount of internal hold time provided
for the SDA input relative to the SCL input. Units are
40 nanoseconds.
3:0
RW
I2C Filter
Depth
Configures the maximum width of glitch pulses on the
SCL and SDA inputs that will be rejected. Units are 5
nanoseconds.
Function
Description
I2C Pass All Pass All
0: Enable Forward Control Channel pass-through only
of I2C accesses to I2C Slave IDs matching either the
remote Deserializer Slave ID or the remote Slave ID.
(default)
1: Enable Forward Control Channel pass-through of
all I2C accesses to I2C Slave IDs that do not match
the Serializer I2C Slave ID.
24
0x18
SCL High Time
7:0
RW
0xA1
SCL HIGH
Time
I2C Master SCL High Time
This field configures the high pulse width of the SCL
output when the Serializer is the Master on the local
I2C bus. Units are 40 ns for the nominal oscillator
clock frequency.
25
0x19
SCL Low Time
7:0
RW
0xA5
SCL LOW
Time
I2C SCL Low Time
This field configures the low pulse width of the SCL
output when the Serializer is the Master on the local
I2C bus. This value is also used as the SDA setup
time by the I2C Slave for providing data prior to
releasing SCL during accesses over the Bidirectional
Control Channel. Units are 40 ns for the nominal
oscillator clock frequency.
26
0x1A
Data Path
Control 2
7
RW
0x00
Block I2S
Block automatic I2S mode configuration
Auto Config (repeater only)
0: I2S mode (2-channel, 4-channel, or surround) is
detected from the in-band audio signaling
1: Disable automatic detection of I2S mode
6:1
27
0x1B
BIST BC Error
Count
Reserved
0
RW
7:0
R
0x00
I2S
Surround
Enable 5.1- or 7.1-channel I2S audio transport
0: 2-channel or 4-channel I2S audio is enabled as
configured in register 0x12 bits 3 and 0 (default)
1: 5.1- or 7.1-channel audio is enabled
Note that I2S Data Island Transport is the only option
for surround audio. Also note that in a repeater, this
bit may be overridden by the in-band I2S mode
detection.
BIST BC
Errorr
BIST Back Channel CRC Error Counter
This register stores the back-channel CRC error count
during BIST Mode (saturates at 255 errors). Clears
when a new BIST is initiated or by 0x04[5]
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Register Maps (continued)
Table 5. Serial Control Bus Registers (continued)
ADD
(dec)
ADD
(hex)
28
0x1C
Register Name
Bit
Register
Type
Default
(hex)
7
R
0x00
6
R
GPIO_REG GPIO_REG6 Input Pin Status
6 Pin Status Status valid only if set to GPI (input) mode
5
R
GPIO_REG GPIO_REG5 Input Pin Status
5 Pin Status Status valid only if set to GPI (input) mode
3
R
GPIO3 Pin
Status
GPIO3 Input Pin Status
Status valid only if set to GPI (input) mode
2
R
GPIO2 Pin
Status
GPIO2 Input Pin Status
Status valid only if set to GPI (input) mode
1
R
GPIO1 Pin
Status
GPIO1 Input Pin Status
Status valid only if set to GPI (input) mode
0
R
GPIO0 Pin
Status
GPIO0 Input Pin Status
Status valid only if set to GPI (input) mode
GPIO Pin
Status 1
Function
GPIO_REG GPIO_REG7 Input Pin Status
7 Pin Status Status valid only if set to GPI (input) mode
4
29
0x1D
Reserved
GPIO Pin
Status 2
7:1
0
R
0x00
Reserved
GPIO_REG GPIO_REG8 Input Pin Status
8 Pin Status Status valid only if set to GPI (input) mode
30
0x1F
Frequency
Counter
7:0
RW
0x00
Frequency
Counter
32
0x20
Deserializer
Capabilities
7
RW
0x00
Freeze DES Freeze Deserializer Capabilities
CAP
Prevent auto-loading of the Deserializer Capabilities
by the Bidirectional Control Channel. The Capabilities
will be frozen at the values written in registers 0x20
and 0x21.
0: Normal operation (default)
1: Freeze
6:2
40
Description
Frequency Counter Control
Write: Measure number of pixel clock periods in
written interval (40ns units)
Read: Return number of pixel clock periods counted
Reserved
1
RW
HD Audio
Deserializer supports 24-bit video concurrently with
HD audio
This field is automatically configured by the
Bidirectional Control Channel once RX Lock has been
detected. Software may overwrite this value, but must
also set the FREEZE DES CAP bit to prevent
overwriting by the Bidirectional Control Channel.
0: Normal operation (default)
1: Freeze
0
RW
FC GPIO
Deserializer supports GPIO in the Forward Channel
Frame
This field is automatically configured by the
Bidirectional Control Channel once RX Lock has been
detected. Software may overwrite this value, but must
also set the FREEZE DES CAP bit to prevent
overwriting by the Bidirectional Control Channel.
0: Normal operation (default)
1: Freeze
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Register Maps (continued)
Table 5. Serial Control Bus Registers (continued)
ADD
(dec)
ADD
(hex)
100
0x64
Register Name
Bit
Register
Type
Default
(hex)
Pattern
Generator
Control
7:4
RW
0x10
Function
Description
Pattern
Generator
Select
Fixed Pattern Select
Selects the pattern to output when in Fixed Pattern
Mode. Scaled patterns are evenly distributed across
the horizontal or vertical active regions. This field is
ignored when Auto-Scrolling Mode is enabled.
xxxx: normal/inverted
0000: Checkerboard
0001: White/Black (default)
0010: Black/White
0011: Red/Cyan
0100: Green/Magenta
0101: Blue/Yellow
0110: Horizontal Black-White/White-Black
0111: Horizontal Black-Red/White-Cyan
1000: Horizontal Black-Green/White-Magenta
1001: Horizontal Black-Blue/White-Yellow
1010: Vertical Black-White/White— Black
1011: Vertically Scaled Black to Red/White to Cyan
1100: Vertical Black-Green/White-Magenta
1101: Vertical Black-Blue/White-Yellow
1110: Custom color (or its inversion) configured in
PGRS, PGGS, PGBS registers
1111: VCOM
See TI App Note AN-2198 Exploring the Internal Test
Pattern Generation Feature of 720p (SNLA132).
3
Reserved
2
RW
Color Bars
Pattern
Enable Color Bars
0: Color Bars disabled (default)
1: Color Bars enabled
Overrides the selection from reg_0x64[7:4]
1
RW
VCOM
Pattern
Reverse
Reverse order of color bands in VCOM pattern
0: Color sequence from top left is (YCBR) (default)
1: Color sequence from top left is (RBCY)
0
RW
Pattern
Generator
Enable
Pattern Generator Enable
0: Disable Pattern Generator (default)
1: Enable Pattern Generator
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Register Maps (continued)
Table 5. Serial Control Bus Registers (continued)
ADD
(dec)
ADD
(hex)
101
0x65
102
42
0x66
Register Name
Bit
Pattern
Generator
Configuration
PGIA
Register
Type
7
Default
(hex)
Function
0x00
Description
Reserved
6
RW
Checkerboa Scale Checkered Patterns:
rd Scale
0: Normal operation (each square is 1x1 pixel)
(default)
1: Scale checkered patterns (VCOM and
checkerboard) by 8 (each square is 8x8 pixels)
Setting this bit gives better visibility of the checkered
patterns.
5
RW
Custom
Use Custom Checkerboard Color
Checkerboa 0: Use white and black in the Checkerboard pattern
rd
(default)
1: Use the Custom Color and black in the
Checkerboard pattern
4
RW
PG 18–bit
Mode
18-bit Mode Select:
0: Enable 24-bit pattern generation. Scaled patterns
use 256 levels of brightness. (default)
1: Enable 18-bit color pattern generation. Scaled
patterns will have 64 levels of brightness and the R,
G, and B outputs use the six most significant color
bits.
3
RW
External
Clock
Select External Clock Source:
0: Selects the internal divided clock when using
internal timing (default)
1: Selects the external pixel clock when using internal
timing. This bit has no effect in external timing mode
(PATGEN_TSEL = 0).
2
RW
Timing
Select
Timing Select Control:
0: the Pattern Generator uses external video timing
from the pixel clock, Data Enable, Horizontal Sync,
and Vertical Sync signals. (default)
1: The Pattern Generator creates its own video timing
as configured in the Pattern Generator Total Frame
Size, Active Frame Size. Horizontal Sync Width,
Vertical Sync Width, Horizontal Back Porch, Vertical
Back Porch, and Sync Configuration registers.
See TI App Note AN-2198 Exploring the Internal Test
Pattern Generation Feature of 720p (SNLA132).
1
RW
Color Invert
Enable Inverted Color Patterns:
0: Do not invert the color output. (default)
1: Invert the color output.
See TI App Note AN-2198 Exploring the Internal Test
Pattern Generation Feature of 720p (SNLA132).
0
RW
Auto Scroll
Auto Scroll Enable:
0: The Pattern Generator retains the current pattern.
(default)
1: The Pattern Generator will automatically move to
the next enabled pattern after the number of frames
specified in the Pattern Generator Frame Time
(PGFT) register.
See TI App Note AN-2198 Exploring the Internal Test
Pattern Generation Feature of 720p (SNLA132).
7:0
RW
PG Indirect
Address
This 8-bit field sets the indirect address for accesses
to indirectly-mapped registers. It should be written
prior to reading or writing the Pattern Generator
Indirect Data register.
See TI App Note AN-2198 Exploring the Internal Test
Pattern Generation Feature of 720p (SNLA132)
0x00
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Register Maps (continued)
Table 5. Serial Control Bus Registers (continued)
ADD
(dec)
ADD
(hex)
Register Name
Bit
Register
Type
Default
(hex)
103
0x67
PGID
7:0
RW
112
0x70
Slave ID[1]
7:1
113
0x71
Slave ID[2]
7:1
114
0x72
Slave ID[3]
7:1
115
0x73
Slave ID[4]
7:1
116
0x74
Slave ID[5]
7:1
Function
Description
0x00
PG Indirect
Data
When writing to indirect registers, this register
contains the data to be written. When reading from
indirect registers, this register contains the read back
value.
See TI App Note AN-2198 Exploring the Internal Test
Pattern Generation Feature of 720p (SNLA132)
RW
0x00
Slave ID 1
7-bit Remote Slave Device ID 1
Configures the physical I2C address of the remote I2C
Slave device attached to the remote Deserializer. If an
I2C transaction is addressed to the Slave Alias ID1,
the transaction will be remapped to this address
before passing the transaction across the Bidirectional
Control Channel to the Deserializer.
RW
0x00
Slave ID 2
RW
0x00
Slave ID 3
RW
0x00
Slave ID 4
RW
0x00
Slave ID 5
0
Reserved
0
Reserved
0
Slave ID[6]
7:1
0
7-bit Remote Slave Device ID 4
Configures the physical I2C address of the remote I2C
Slave device attached to the remote Deserializer. If an
I2C transaction is addressed to the Slave Alias ID4,
the transaction will be remapped to this address
before passing the transaction across the Bidirectional
Control Channel to the Deserializer.
Reserved
0
0x75
7-bit Remote Slave Device ID 3
Configures the physical I2C address of the remote I2C
Slave device attached to the remote Deserializer. If an
I2C transaction is addressed to the Slave Alias ID3,
the transaction will be remapped to this address
before passing the transaction across the Bidirectional
Control Channel to the Deserializer.
Reserved
0
117
7-bit Remote Slave Device ID 2
Configures the physical I2C address of the remote I2C
Slave device attached to the remote Deserializer. If an
I2C transaction is addressed to the Slave Alias ID2,
the transaction will be remapped to this address
before passing the transaction across the Bidirectional
Control Channel to the Deserializer.
7-bit Remote Slave Device ID 5
Configures the physical I2C address of the remote I2C
Slave device attached to the remote Deserializer. If an
I2C transaction is addressed to the Slave Alias ID5,
the transaction will be remapped to this address
before passing the transaction across the Bidirectional
Control Channel to the Deserializer.
Reserved
RW
0x00
Slave ID 6
7-bit Remote Slave Device ID 6
Configures the physical I2C address of the remote I2C
Slave device attached to the remote Deserializer. If an
I2C transaction is addressed to the Slave Alias ID6,
the transaction will be remapped to this address
before passing the transaction across the Bidirectional
Control Channel to the Deserializer.
Reserved
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Register Maps (continued)
Table 5. Serial Control Bus Registers (continued)
ADD
(dec)
ADD
(hex)
Register Name
Bit
Register
Type
Default
(hex)
Function
Description
118
0x76
Slave ID[7]
7:1
RW
0x00
Slave ID 7
7-bit Remote Slave Device ID 7
Configures the physical I2C address of the remote I2C
Slave device attached to the remote Deserializer. If an
I2C transaction is addressed to the Slave Alias ID7,
the transaction will be remapped to this address
before passing the transaction across the Bidirectional
Control Channel to the Deserializer.
0
119
0x77
Slave Alias[1]
7:1
Reserved
RW
0x00
Slave Alias
ID 1
0
120
0x78
Slave Alias[2]
7:1
Reserved
RW
0x00
Slave Alias
ID 2
0
121
0x79
Slave Alias[3]
7:1
122
0x7A
Slave Alias[4]
7:1
123
0x7B
Slave Alias[5]
7:1
124
0x7C
Slave Alias[6]
7:1
RW
0x00
Slave Alias
ID 3
RW
0x00
Slave Alias
ID 4
RW
0x00
Slave Alias
ID 5
RW
0x00
Slave Alias
ID 6
7-bit Remote Slave Device Alias ID 3
Configures the decoder for detecting transactions
designated for an I2C Slave device attached to the
remote Deserializer. The transaction will be remapped
to the address specified in the Slave ID3 register. A
value of 0 in this field disables access to the remote
I2C Slave.
Reserved
0
7-bit Remote Slave Device Alias ID 4
Configures the decoder for detecting transactions
designated for an I2C Slave device attached to the
remote Deserializer. The transaction will be remapped
to the address specified in the Slave ID4 register. A
value of 0 in this field disables access to the remote
I2C Slave.
Reserved
0
44
7-bit Remote Slave Device Alias ID 2
Configures the decoder for detecting transactions
designated for an I2C Slave device attached to the
remote Deserializer. The transaction will be remapped
to the address specified in the Slave ID2 register. A
value of 0 in this field disables access to the remote
I2C Slave.
Reserved
0
0
7-bit Remote Slave Device Alias ID 1
Configures the decoder for detecting transactions
designated for an I2C Slave device attached to the
remote Deserializer. The transaction will be remapped
to the address specified in the Slave ID1 register. A
value of 0 in this field disables access to the remote
I2C Slave.
7-bit Remote Slave Device Alias ID 5
Configures the decoder for detecting transactions
designated for an I2C Slave device attached to the
remote Deserializer. The transaction will be remapped
to the address specified in the Slave ID5 register. A
value of 0 in this field disables access to the remote
I2C Slave.
Reserved
7-bit Remote Slave Device Alias ID 6
Configures the decoder for detecting transactions
designated for an I2C Slave device attached to the
remote Deserializer. The transaction will be remapped
to the address specified in the Slave ID6 register. A
value of 0 in this field disables access to the remote
I2C Slave.
Reserved
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Register Maps (continued)
Table 5. Serial Control Bus Registers (continued)
ADD
(dec)
ADD
(hex)
Register Name
Bit
Register
Type
Default
(hex)
125
0x7D
Slave Alias[7]
7:1
RW
0x00
Function
Description
Slave Alias
ID 7
7-bit Remote Slave Device Alias ID 7
Configures the decoder for detecting transactions
designated for an I2C Slave device attached to the
remote Deserializer. The transaction will be remapped
to the address specified in the Slave ID7 register. A
value of 0 in this field disables access to the remote
I2C Slave.
0
Reserved
128
0x80
RX_BKSV0
7:0
R
0x00
RX BKSV0
BKSV0: Value of byte 0 of the Deserializer KSV
129
0x81
RX_BKSV1
7:0
R
0x00
RX BKSV1
BKSV1: Value of byte 1 of the Deserializer KSV
130
0x82
RX_BKSV2
7:0
R
0x00
RX BKSV2
BKSV2: Value of byte 2 of the Deserializer KSV
131
0x83
RX_BKSV3
7:0
R
0x00
RX BKSV3
BKSV3: Value of byte 3 of the Deserializer KSV.
132
0x84
RX_BKSV4
7:0
R
0x00
RX BKSV4
BKSV4: Value of byte 4 of the Deserializer KSV.
144
0x90
TX_KSV0
7:0
R
0x00
TX KSV0
KSV0: Value of byte 0 of the Serializer KSV.
145
0x91
TX_KSV1
7:0
R
0x00
TX KSV1
KSV1: Value of byte 1 of the Serializer KSV.
146
0x92
TX_KSV2
7:0
R
0x00
TX KSV2
KSV2: Value of byte 2 of the Serializer KSV.
147
0x93
TX_KSV3
7:0
R
0x00
TX KSV3
KSV3: Value of byte 3 of the Serializer KSV.
148
0x94
TX_KSV4
7:0
R
0x00
TX KSV4
KSV4: Value of byte 4 of the Serializer KSV.
152
0x98
TX_AN0
7:0
R
0x00
TX AN0
TX_AN0: Value of byte 0 of the Serializer AN Value
153
0x99
TX_AN1
7:0
R
0x00
TX AN1
TX_AN1: Value of byte 1 of the Serializer AN Value
154
0x9A
TX_AN2
7:0
R
0x00
TX AN2
TX_AN2: Value of byte 2 of the Serializer AN Value
155
0x9B
TX_AN3
7:0
R
0x00
TX AN3
TX_AN3: Value of byte 3 of the Serializer AN Value
156
0x9C
TX_AN4
7:0
R
0x00
TX AN4
TX_AN4: Value of byte 4 of the Serializer AN Value
157
0x9D
TX_AN5
7:0
R
0x00
TX AN5
TX_AN5: Value of byte 5 of the Serializer AN Value
158
0x9E
TX_AN6
7:0
R
0x00
TX AN6
TX_AN6: Value of byte 6 of the Serializer AN Value
159
0x9F
TX_AN7
7:0
R
0x00
TX AN7
TX_AN7: Value of byte 7 of the Serializer AN Value
160
0xA0
RX BCAPS
7
0x00
Reserved
6
R
Repeater
Indicates if the attached Receiver supports
downstream connections. This bit is valid once the
Bksv is ready as indicated by the BKSV_RDY bit in
the HDCP
5
R
KSV FIFO
KSV FIFO Ready
Indicates the receiver has built the list of attached
KSVs and computed the verification value
1
R
Features
HDCP v1.1_Features
The HDCP Receiver supports the Enhanced
Encryption Status Signaling (EESS), Advance Cipher,
and Enhanced Link Verification options.
0
R
Fast Reauth
The HDCP Receiver is capable of receiving
(unencrypted) video signal during the session reauthentication.
7
R
Max
Devices
Maximum Devices Exceeded: Indicates a topology
error was detected. Indicates the number of
downstream devices has exceeded the depth of the
Repeater's KSV FIFO.
6:0
R
Device
Count
Total number of attached downstream device. For a
Repeater, this will indicate the number of downstream
devices, not including the Repeater. For an HDCP
Receiver that is not also a Repeater, this field will be
0.
4:2
161
0xA1
RX BSTATUS0
Reserved
0x00
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Register Maps (continued)
Table 5. Serial Control Bus Registers (continued)
ADD
(dec)
ADD
(hex)
Register Name
Bit
162
0xA2
RX BSTATUS1
7:4
46
Register
Type
Default
(hex)
Function
0x00
Description
Reserved
3
R
Max
Cascade
Maximum Cascade Exceeded: Indicates a topology
error was detected — more than seven levels of
repeaters have been cascaded together.
2:0
R
Cascade
Depth
Indicates the number of attached levels of devices for
the Repeater.
R
KSV FIFO
KSV FIFO
Each read of the KSV FIFO returns one byte of the
KSV FIFO list composed by the downstream
Receiver.
163
0xA3
KSV FIFO
7:0
192
0xC0
HDCP DBG
7:4
0x00
0x00
Reserved
3
RW
RGB
CHKSUM
Enable RGB video line checksum
Enables sending of ones-complement checksum for
each 8-bit RGB data channel following end of each
video data line.
2
RW
Fast LV
Fast Link Verification
HDCP periodically verifies that the HDCP Receiver is
correctly synchronized. Setting this bit will increase
the rate at which synchronization is verified. When set
to a 1, Pj is computed every 2 frames and Ri is
computed every 16 frames. When set to a 0, Pj is
computed every 16 frames and Ri is computed every
128 frames.
1
RW
TMR Speed Timer Speedup
Up
Speed up HDCP authentication timers.
0
RW
HDCP I2C
Fast
HDCP I2C Fast Mode Enable
Setting this bit to a 1 will enable the HDCP I2C Master
in the HDCP Receiver to operate with Fast mode
timing. If set to a 0, the I2C Master will operate with
Standard mode timing. This bit is mirrored in the
IND_STS register.
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Register Maps (continued)
Table 5. Serial Control Bus Registers (continued)
ADD
(dec)
ADD
(hex)
Register Name
194
0xC2
HDCP CFG
Bit
Register
Type
Default
(hex)
Function
Description
7
RW
0x80
ENH LV
Enable Enhanced Link Verification
Allows checking of the encryption Pj value on every
16th frame.
0: Enhanced Link Verification disabled
1: Enhanced Link Verification enabled (default)
6
RW
HDCP
EESS
Enables Enhanced Encryption Status Signaling
(EESS) instead of the Original Encryption Status
Signaling (OESS).
0: OESS mode enabled (default)
1: EESS mode enabled
5
RW
TX RPTR
Transmit Repeater Enable
Enables the transmitter to act as a repeater. In this
mode, the HDCP Transmitter incorporates the
additional authentication steps required of an HDCP
Repeater.
0: Transmit Repeater mode disabled (default)
1: Transmit Repeater mode enabled
4:3
RW
ENC Mode
Encryption Control Mode
Determines mode for controlling whether encryption is
required for video frames.
00: Enc_Authenticated (default)
01: Enc_Reg_Control
10: Enc_Always
11: Enc_InBand_Control (per frame)
If the Repeater strap option is set at power-up,
Enc_InBand_Control (ENC_MODE == 11) will be
selected. Otherwise, the default will be
Enc_Authenticated mode (ENC_MODE == 00).
2
RW
Wait
Enable 100 ms Wait: The HDCP 1.3 specification
allows for a 100 ms wait to allow the HDCP Receiver
to compute the initial encryption values. The FPD-Link
III implementation ensures that the Receiver will
complete the computations before the HDCP
Transmitter. Thus the timer is unnecessary.
0: 100 ms timer disabled (default)
1: 100 ms timer enabled
1
RW
RX DET
SEL
RX Detect Select: Controls assertion of the Receiver
Detect Interrupt.
0: The Receiver Detect Interrupt will be asserted on
detection of an FPD-Link III Receiver. (default)
1: the Receiver Detect Interrupt will also require a
receive lock indication from the receiver.
0
RW
HDCP AV
MUTE
Enable AVMUTE This bit may only be set if the
HDCP_EESS bit is also set.
0: Resume normal operation (default)
1: Initiate AVMUTE operation. The transmitter will
ignore encryption status controls while in this state.
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Register Maps (continued)
Table 5. Serial Control Bus Registers (continued)
ADD
(dec)
ADD
(hex)
Register Name
195
0xC3
HDCP CTL
Bit
Register
Type
Default
(hex)
7
RW
0x00
Function
Description
HDCP RST
HDCP Reset
Setting this bit will reset the HDCP transmitter and
disable HDCP authentication. This bit is self-clearing.
6
48
Reserved
5
RW
KSV List
Valid
The controller sets this bit after validating the
Repeater’s KSV List against the Key revocation list.
This allows completion of the Authentication process.
This bit is self-clearing.
4
RW
KSV Valid
The controller sets this bit after validating the
Receiver’s KSV against the Key revocation list. This
allows continuation of the Authentication process. This
bit will be cleared upon assertion of the KSV_RDY
flag in the HDCP_STS register. Setting this bit to a 0
will have no effect.
3
RW
HDCP ENC HDCP Encrypt Disable
DIS
Disables HDCP encryption. Setting this bit to a 1 will
cause video data to be sent without encryption.
Authentication status will be maintained. This bit is
self-clearing.
2
RW
HDCP ENC HDCP Encrypt Enable
EN
Enables HDCP encryption. When set, if the device is
authenticated, encrypted data will be sent. If device is
not authenticated, a blue screen will be sent.
Encryption should always be enabled when video
data requiring content protection is being supplied to
the transmitter. When this bit is not set, video data will
be sent without encryption. Note that when
CFG_ENC_MODE is set to Enc_Always, this bit will
be read only with a value of 1.
1
RW
HDCP DIS
HDCP Disable
Disables HDCP authentication. Setting this bit to a 1
will disable the HDCP authentication.
This bit is self-clearing.
0
RW
HDCP EN
HDCP Enable/Restart
Enables HDCP authentication. If HDCP is already
enabled, setting this bit to a 1 will restart
authentication. Setting this bit to a 0 will have no
effect. A register read will return the current HDCP
enabled status.
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Register Maps (continued)
Table 5. Serial Control Bus Registers (continued)
ADD
(dec)
ADD
(hex)
Register Name
196
0xC4
HDCP STS
Bit
Register
Type
Default
(hex)
7
R
0x00
6
Function
Description
I2C ERR
DET
HDCP I2C Error Detected
This bit indicates an error was detected on the
embedded communications channel with the HDCP
Receiver. Setting of this bit might indicate that a
problem exists on the link between the HDCP
Transmitter and HDCP Receiver. This bit will be
cleared on read.
R
RX INT
RX Interrupt
Status of the RX Interrupt signal.
The signal is received from the attached HDCP
Receiver and is the status on the INTB_IN pin of the
HDCP Receiver. The signal is active low, a 0
indicates an interrupt condition.
5
R
RX Lock
DET
Receiver Lock Detect
This bit indicates that the downstream Receiver has
indicated Receive Lock to incoming serial data.
4
R
DOWN
HPD
Downstream Hot Plug Detect
This bit indicates the local device or a downstream
repeater has reported a Hot Plug event, indicating
addition of a new receiver. This bit will be cleared on
read.
3
R
RX DET
Receiver Detect
This bit indicates that a downstream Receiver has
been detected.
2
R
KSV LIST
RDY
HDCP Repeater KSV List Ready
This bit indicates that the Receiver KSV list has been
read and is available in the KSV_FIFO registers. The
device will wait for the controller to set the
KSV_LIST_VALID bit in the HDCP_CTL register
before continuing. This bit will be cleared once the
controller sets the KSV_LIST_VALID bit.
1
R
KSV RDY
HDCP Receiver KSV Ready
This bit indicates that the Receiver KSV has been
read and is available in the HDCP_ BKSV registers. If
the device is not a Repeater, it will wait for the
controller to set the KSV_VALID bit in the HDCP_CTL
register before continuing.
This bit will be cleared once the controller sets the
KSV_VALID bit.. The bit will also be cleared if
authentication fails.
0
R
AUTHED
HDCP Authenticated
Indicates the HDCP authentication has completed
successfully. The controller may now send video data
requiring content protection. This bit will be cleared if
authentication is lost or if the controller restarts
authentication.
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Register Maps (continued)
Table 5. Serial Control Bus Registers (continued)
ADD
(dec)
ADD
(hex)
Register Name
198
0xC6
HDCP ICR
199
50
0xC7
Bit
Register
Type
Default
(hex)
7
RW
0x00
6
RW
IE RXDET
INT
Interrupt on Receiver Detect
Enables interrupt on detection of a downstream
Receiver. If HDCP_CFG:RX_DET_SEL is set to a 1,
the interrupt will wait for Receiver Lock Detect.
5
RW
IS_RX_INT
Interrupt on Receiver Interrupt
Enables interrupt on indication from the HDCP
Receiver. Allows propagation of interrupts from
downstream devices.
4
RW
IE LIST
RDY
Interrupt on KSV List Ready
Enables interrupt on KSV List Ready.
3
RW
IE KSV
RDY
Interrupt on KSV Ready
Enables interrupt on KSV Ready.
2
RW
IE AUTH
FAIL
Interrupt on Authentication Failure
Enables interrupt on authentication failure or loss of
authentication.
1
RW
IE AUTH
PASS
Interrupt on Authentication Pass
Enables interrupt on successful completion of
authentication.
0
RW
INT Enable
Global Interrupt Enable
Enables interrupt on the interrupt signal to the
controller.
7
R
6
R
INT Detect
Interrupt on Receiver Detect interrupt
A downstream receiver has been detected.
5
R
IS RX INT
Interrupt on Receiver interrupt
Receiver has indicated an interrupt request from
downstream device.
4
R
IS LIST
RDY
Interrupt on KSV List Ready
The KSV list is ready for reading by the controller.
3
R
IS KSV
RDY
Interrupt on KSV Ready
The Receiver KSV is ready for reading by the
controller.
2
R
IS AUTH
FAIL
Interrupt on Authentication Failure
Authentication failure or loss of authentication has
occurred.
1
R
IS AUTH
PASS
Interrupt on Authentication Pass
Authentication has completed successfully.
0
R
INT
Global Interrupt
Set if any enabled interrupt is indicated.
HDCP ISR
0x00
Function
Description
IE IND ACC Interrupt on Indirect Access Complete
Enables interrupt on completion of Indirect Register
Access.
IS IND ACC Interrupt on Indirect Access Complete
Indirect Register Access has completed.
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Register Maps (continued)
Table 5. Serial Control Bus Registers (continued)
ADD
(dec)
ADD
(hex)
Register Name
208
0xD0
IND STS
Bit
Register
Type
Default
(hex)
Function
Description
7
RW
0x00
IA Reset
Indirect Access Reset
Setting this bit to a 1 will reset the I2C Master in the
HDCP Receiver. As this may leave the I2C bus in an
indeterminate state, it should only be done if the
Indirect Access mechanism is not able to complete
due to an error on the destination I2C bus.
6
Reserved
5
RW
I2C TO DIS
I2C Timeout Disable
Setting this bit to a 1 will disable the bus timeout
function in the I2C master. When enabled, the bus
timeout function allows the I2C master to assume the
bus is free if no signaling occurs for more than 1
second.
4
RW
I2C Fast
I2C Fast mode Enable
Setting this bit to a 1 will enable the I2C Master in the
HDCP Receiver to operation with Fast mode timing. If
set to a 0 (default), the I2C Master will operate with
Standard mode timing.
1
R
IA ACK
Indirect Access Acknowledge
The acknowledge bit indicates that a valid
acknowledge was received upon completion of the I2C
read or write to the slave. A value of 0 (default)
indicates the read/write did not complete successfully.
0
R
IA DONE
Indirect Access Done
Set to a 1 to indicate completion of Indirect Register
Access. This bit will be cleared or read or by start of a
new Indirect Register Access.
7:1
RW
IA SADDR
Indirect Access Slave Address
This field should be programmed with the slave
address for the I2C slave to be accessed.
0
RW
IA RW
Indirect Access Read/Write
0: Write (default)
1: Read
3:2
209
0xD1
IND SAR
Reserved
0x00
210
0xD2
IND OAR
7:0
RW
0x00
IA Offset
Indirect Access Offset
It is programmed with the register address for the I2C
indirect access.
211
0xD3
IND DATA
7:0
RW
0x00
IA Data
Indirect Access Data
For an indirect write, It is written with the write data.
For an indirect read, it contains the result of a
successful read.
240
0xF0
HDCP TX ID
7:0
R
0x5F
ID0
First byte ID code, ‘_’
241
0xF1
7:0
R
0x55
ID1
Second byte of ID code, ‘U’
242
0xF2
7:0
R
0x48
ID2
Third byte of ID code. ‘H'
243
0xF3
7:0
R
0x39
ID3
Forth byte of ID code: ‘9’
244
0xF4
7:0
R
0x32
ID4
Fifth byte of ID code: “2”
245
0xF5
7:0
R
0x37
ID5
Sixth byte of ID code: “7”
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8 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.
8.1 Application Information
The DS90UH927Q-Q1, in conjunction with the DS90UH928Q-Q1 or DS90UH926Q-Q1, is intended for interface
between a HDCP compliant host (graphics processor) and a display supporting 24-bit color depth (RGB888) and
high definition (720p) digital video format. It can receive an 8-bit RGB stream with a pixel clock rate up to 85 MHz
together with three control bits (VS, HS and DE) and four I2S audio streams. The included HDCP 1.3 compliant
cipher block allows the authentication of the HDCP Deserializer, which decrypts both video and audio contents.
The HDCP keys are pre-loaded by TI into Non-Volatile Memory (NVM) for maximum security.
8.2 Typical Application
Figure 29 shows a typical application of the DS90UH927Q-Q1 serializer for an 85 MHz 24-bit Color Display
Application. The 5 LVDS input pairs require external 100Ω terminations. The CML outputs must have an external
0.1-µF AC coupling capacitor on the high speed serial lines. The serializer has internal CML termination on its
high speed outputs.
Bypass capacitors should be placed near the power supply pins. At a minimum, four (4) 4.7-µF capacitors should
be used for local device bypassing. Ferrite beads are placed on the two sets of supply pins (VDD33 and VDDIO)
for effective noise suppression. The interface to the graphics source is LVDS. The VDDIO pins may be
connected to 3.3 V or 1.8 V. A capacitor and resistor are placed on the PDB pin to delay the enabling of the
device until power is stable.
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Typical Application (continued)
DS90UH927Q-Q1
3.3V or 1.8V (VDDIO)
VDDIO
VDD33_A
C6
FB1
3.3V (VDD33)
C4
VDDIO
FB2
VDD33_B
C5
C7
CAPLVD12
CAPL12
C11
C8
CAPP12
C9
CAPHS12
C12
C10
C1
RxCLKIN-
DOUT+
RxCLKIN+
DOUT-
100:
CMF
RxIN3100:
Serial
FPD-Link III
Interface
C2
C3
RxIN3+
RxIN2-
FPD-Link
Interface
100:
RxIN2+
RxIN1100:
MAPSEL
RxIN1+
RxIN0100:
LVCMOS
Control
Interface
BKWD
LFMODE
REPEAT
RxIN0+
4.7K
R4
VDDIO
R5
4.7K
VDD33
VDD33
IDx
SCL
SDA
INTB
PDB
R1
Notes:
FB1-FB2: Impedance = 1k:@100MHz
Low DC resistance (<1:)
R2
C1-C3 = 0.1 PF
(50 WV; C1, C2: 0402; C3: 0603)
C4-C12 = 4.7 PF
C13 = >10 PF
R1/R2: see IDx Resistor Value Table
R4 = 10k:
R5= 4.7k:
C13
I2S_CLK
I2S_WC
I2S_Dx
4
RESx
DAP (GND)
Figure 29. Typical Connection Diagram
FPD-Link
FPD-Link
VDDIO
VDD33
(3.3V) (1.8V or 3.3V)
HOST
Graphics
Processor
FPD-Link Display Interface
VDD33
VDDIO
(1.8V or 3.3V) (3.3V)
RxIN3+/-
RxIN1+/RxIN0+/RxCLKIN+/-
TxOUT3+/-
FPD-Link III
1 Pair/AC Coupled
RxIN2+/-
TxOUT2+/-
DOUT+
RIN+
DOUT-
RIN100Q STP Cable
DS90UH927Q-Q1
Serializer
PDB
INTB
I2S 6
SCL
SDA
IDx
MAPSEL
LFMODE
REPEAT
BKWD
OEN
OSS_SEL
PDB
MAPSEL
LFMODE
BISTEN
MODE_SEL
DS90UH928Q-Q1
Deserializer
TxOUT1+/TxOUT0+/-
RGB Display
720p
24-bit Color Depth
TxCLKOUT+/INTB_IN
LOCK
PASS
6
I2S
MCLK
SCL
SDA
IDx
Figure 30. Display Application
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Typical Application (continued)
8.2.1 Design Requirements
For the typical design application, use the following as input parameters.
Table 6. Design Parameters
DESIGN PARAMETER
EXAMPLE VALUE
VDDIO
1.8 V or 3.3 V
VDD33
3.3 V
AC Coupling Capacitor for DOUT±
100 nF
PCLK Frequency
85 MHz
8.2.2 Detailed Design Procedure
Figure 29 shows a typical application of the DS90UH927Q-Q1 serializer for an 85-MHz 24-bit Color Display
Application. The CML outputs must have an external 0.1-μF AC coupling capacitor on the high speed serial lines.
Bypass capacitors are placed near the power supply pins. At a minimum, six (6) 4.7-μF capacitors and two (2)
additional 1-μF capacitors should be used for local device bypassing. Ferrite beads are placed on the two (2)
VDDs (VDD33 and VDDIO) for effective noise suppression. An RC delay is placed on the PDB signal to delay
the enabling of the device until power is stable.
8.2.3 Application Curves
Figure 31. Serializer Output Stream with 48-MHz Input
Clock
Figure 32. Serializer Eye with 48-MHz Input Clock
9 Power Supply Recommendations
The power supply ramp (VDD33 and VDDIO) should be faster than 1.5 ms with a monotonic rise. A large capacitor
on the PDB pin is needed to ensure PDB arrives after all the supply pins have settled to the recommended
operating voltage. When PDB pin is pulled up to VDD33, a 10-kΩ pullup and a > 10-μF capacitor to GND are
required to delay the PDB input signal rise. All inputs must not be driven until both VDD33 and VDDIO has reached
steady state. Pins VDD33_A and VDD33_B should both be externally connected, bypassed, and driven to the
same potential (they are not internally connected).
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10 Layout
10.1 Layout Guidelines
Circuit board layout and stack-up for the LVDS serializer and deserializer devices should be designed to provide
low-noise power to the device. Good layout practice will also separate high frequency or high-level inputs and
outputs to minimize unwanted stray noise, feedback and interference. Power system performance may be greatly
improved by using thin dielectrics (2 to 4 mil) for power / ground sandwiches. This arrangement utilizes the plane
capacitance for the PCB power system and has low-inductance, which has proven effectiveness especially at
high frequencies, and makes the value and placement of external bypass capacitors less critical. External bypass
capacitors should include both RF ceramic and tantalum electrolytic types. RF capacitors may use values in the
range of 0.01 μF to 10 μF. Tantalum capacitors may be in the 2.2 μF to 10 μF range. The voltage rating of the
tantalum capacitors should be at least 5X the power supply voltage being used.
MLCC surface mount capacitors are recommended due to their smaller parasitic properties. When using multiple
capacitors per supply pin, locate the smaller value closer to the pin. A large bulk capacitor is recommended at
the point of power entry. This is typically in the 50 μF to 100 μF range and will smooth low frequency switching
noise. It is recommended to connect power and ground pins directly to the power and ground planes with bypass
capacitors connected to the plane with via on both ends of the capacitor. Connecting power or ground pins to an
external bypass capacitor will increase the inductance of the path. A small body size X7R chip capacitor, such as
0603 or 0805, is recommended for external bypass. A small body sized capacitor has less inductance. The user
must pay attention to the resonance frequency of these external bypass capacitors, usually in the range of 20
MHz to 30 MHz. To provide effective bypassing, multiple capacitors are often used to achieve low impedance
between the supply rails over the frequency of interest. At high frequency, it is also a common practice to use
two vias from power and ground pins to the planes, reducing the impedance at high frequency.
Some devices provide separate power and ground pins for different portions of the circuit. This is done to isolate
switching noise effects between different sections of the circuit. Separate planes on the PCB are typically not
required. Pin Description tables typically provide guidance on which circuit blocks are connected to which power
pin pairs. In some cases, an external filter may be used to provide clean power to sensitive circuits such as
PLLs. For DS90UH927Q-Q1, only one common ground plane is required to connect all device related ground
pins.
Use at least a four layer board with a power and ground plane. Locate LVCMOS signals away from the LVDS
lines to prevent coupling from the LVCMOS lines to the LVDS lines. Closely coupled differential lines of 100 Ω
are typically recommended for LVDS interconnect. The closely coupled lines help to ensure that coupled noise
will appear as common mode and thus is rejected by the receivers. The tightly coupled lines will also radiate
less.
At least 9 thermal vias are necessary from the device center DAP to the ground plane. They connect the device
ground to the PCB ground plane, as well as conduct heat from the exposed pad of the package to the PCB
ground plane. More information on the WQFN style package, including PCB design and manufacturing
requirements, is provided in TI Application Note: AN-1187 Leadless Leadframe Package (LLP) (SNOA401).
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Layout Guidelines (continued)
10.1.1 CML Interconnect Guidelines
See SNLA008 and SNLA035 for full details.
• Use 100-Ω coupled differential pairs
• Use the S/2S/3S rule in spacings
– – S = space between the pair
– – 2S = space between pairs
– – 3S = space to LVCMOS signal
• Minimize the number of Vias
• Use differential connectors when operating above 500 Mbps line speed
• Maintain balance of the traces
• Minimize skew within the pair
• Terminate as close to the TX outputs and RX inputs as possible.
Additional general guidance can be found in the LVDS Owner’s Manual - available in PDF format from the Texas
Instruments web site at: http://www.ti.com/lit/ml/snla187/snla187.pdf
10.2 Layout Example
Notes:
1. All linear dimensions are in millimeters. Any dimensions in parenthesis are for reference only. Dimensioning
and tolerancing per ASME Y14.5M
2. This drawing is subject to change without notice.
3. The package thermal pad must be soldered to the printed circuit board for thermal and mechanical
performance.
4. This package is designed to be soldered to a thermal pad on the board. For more information, see Texas
Instruments literature number SLUA271.
5. Laser cutting apertures with trapezoidal walls and rounded corners may offer better paste release. IPC-7525
may have alternate design recommendations.
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Layout Example (continued)
( 4.6)
SYMM
31
40
40X (0.6)
40X (0.25)
1
30
36X (0.5)
(0.74)
TYP
SYMM
(5.8)
(1.48)
TYP
( 0.2) TYP
VIA
10
21
(R0.05) TYP
20
11
(0.74) TYP
(1.48) TYP
(5.8)
LAND PATTERN EXAMPLE
SCALE:12X
0.07 MIN
ALL AROUND
0.07 MAX
ALL AROUND
SOLDER MASK
OPENING
METAL
SOLDER MASK
OPENING
NON SOLDER MASK
DEFINED
(PREFERRED)
METAL UNDER
SOLDER MASK
SOLDER MASK
DEFINED
SOLDER MASK DETAILS
Figure 33. Land Pattern Example and Solder Mask Details
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Layout Example (continued)
(1.48) TYP
9X ( 1.28)
31
40
40X (0.6)
1
30
40X (0.25)
36X (0.5)
(1.48)
TYP
SYMM
(5.8)
METAL
TYP
10
21
(R0.05) TYP
20
11
SYMM
(5.8)
SOLDER PASTE EXAMPLE
BASED ON 0.125 mm THICK STENCIL
EXPOSED PAD
70% PRINTED SOLDER COVERAGE BY AREA
SCALE:15X
Figure 34. Solder Paste Example
Figure 35 PCB layout example is derived from the layout design of the DS90UH927Q-Q1 Evaluation Board. The
graphic and layout description are used to determine both proper routing and proper solder techniques when
designing the Serializer board.
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Layout Example (continued)
AC Capacitors
LengthMatched
OLDI Traces
High-Speed
Traces
Figure 35. DS90UH927Q-Q1 Serializer Example Layout
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11 Device and Documentation Support
11.1 Documentation Support
11.1.1 Related Documentation
For related documentation, see the following:
• AN-2198 Exploring the Internal Test Pattern Generation Feature of 720p, SNLA132
• I2C Communication Over FPD-Link III with Bidirectional Control Channel, SNLA131
• AN-1187 Leadless Leadframe Package (LLP), SNOA401
• AN-1108 Channel-Link PCB and Interconnect Design-In Guidelines, SNLA008
• AN-905 Transmission Line RAPIDESIGNER Operation and Applications Guide, SNLA035
• LVDS Owner’s Manual, SNLA187
• QFN/SON PCB Attachment, SLUA271
11.2 Trademarks
All trademarks are the property of their respective owners.
11.3 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.
11.4 Glossary
SLYZ022 — TI Glossary.
This glossary lists and explains terms, acronyms, and definitions.
12 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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PACKAGE OPTION ADDENDUM
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31-Oct-2014
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package Pins Package
Drawing
Qty
Eco Plan
Lead/Ball Finish
MSL Peak Temp
(2)
(6)
(3)
Op Temp (°C)
Device Marking
(4/5)
DS90UH927QSQ/NOPB
ACTIVE
WQFN
RTA
40
1000
Green (RoHS
& no Sb/Br)
CU SN
Level-3-260C-168 HR
-40 to 105
UH927QSQ
DS90UH927QSQE/NOPB
ACTIVE
WQFN
RTA
40
250
Green (RoHS
& no Sb/Br)
CU SN
Level-3-260C-168 HR
-40 to 105
UH927QSQ
DS90UH927QSQX/NOPB
ACTIVE
WQFN
RTA
40
2500
Green (RoHS
& no Sb/Br)
CU SN
Level-3-260C-168 HR
-40 to 105
UH927QSQ
(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.
(4)
There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.
(5)
Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation
of the previous line and the two combined represent the entire Device Marking for that device.
(6)
Lead/Ball Finish - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead/Ball Finish values may wrap to two lines if the finish
value exceeds the maximum column width.
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
Addendum-Page 1
Samples
PACKAGE OPTION ADDENDUM
www.ti.com
31-Oct-2014
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 2
PACKAGE MATERIALS INFORMATION
www.ti.com
31-Oct-2014
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
DS90UH927QSQ/NOPB
Package Package Pins
Type Drawing
WQFN
RTA
40
DS90UH927QSQE/NOPB WQFN
RTA
DS90UH927QSQX/NOPB WQFN
RTA
SPQ
Reel
Reel
A0
Diameter Width (mm)
(mm) W1 (mm)
B0
(mm)
K0
(mm)
P1
(mm)
W
Pin1
(mm) Quadrant
1000
330.0
16.4
6.3
6.3
1.5
12.0
16.0
Q1
40
250
178.0
16.4
6.3
6.3
1.5
12.0
16.0
Q1
40
2500
330.0
16.4
6.3
6.3
1.5
12.0
16.0
Q1
Pack Materials-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
31-Oct-2014
*All dimensions are nominal
Device
Package Type
Package Drawing
Pins
SPQ
Length (mm)
Width (mm)
Height (mm)
DS90UH927QSQ/NOPB
WQFN
RTA
40
1000
367.0
367.0
38.0
DS90UH927QSQE/NOPB
WQFN
RTA
40
250
213.0
191.0
55.0
DS90UH927QSQX/NOPB
WQFN
RTA
40
2500
367.0
367.0
38.0
Pack Materials-Page 2
PACKAGE OUTLINE
RTA0040A
WQFN - 0.8 mm max height
SCALE 2.200
PLASTIC QUAD FLATPACK - NO LEAD
6.1
5.9
A
B
PIN 1 INDEX AREA
6.1
5.9
0.5
0.3
0.3
0.2
DETAIL
OPTIONAL TERMINAL
TYPICAL
0.8 MAX
C
SEATING PLANE
0.08
0.05
0.00
4.6 0.1
36X 0.5
10
(0.1) TYP
EXPOSED
THERMAL PAD
20
11
21
4X
4.5
SEE TERMINAL
DETAIL
1
PIN 1 ID
(OPTIONAL)
30
40
31
40X
0.5
0.3
40X
0.3
0.2
0.1
0.05
C A
B
4214989/A 12/2014
NOTES:
1. All linear dimensions are in millimeters. Any dimensions in parenthesis are for reference only. Dimensioning and tolerancing
per ASME Y14.5M.
2. This drawing is subject to change without notice.
3. The package thermal pad must be soldered to the printed circuit board for thermal and mechanical performance.
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EXAMPLE BOARD LAYOUT
RTA0040A
WQFN - 0.8 mm max height
PLASTIC QUAD FLATPACK - NO LEAD
( 4.6)
SYMM
40X (0.25)
31
40
40X (0.6)
1
30
36X (0.5)
(0.74)
TYP
SYMM
(5.8)
(1.48)
TYP
( 0.2) TYP
VIA
10
21
(R0.05) TYP
11
20
(0.74) TYP
(1.48) TYP
(5.8)
LAND PATTERN EXAMPLE
SCALE:12X
0.07 MIN
ALL AROUND
0.07 MAX
ALL AROUND
SOLDER MASK
OPENING
METAL
SOLDER MASK
OPENING
METAL UNDER
SOLDER MASK
NON SOLDER MASK
DEFINED
(PREFERRED)
SOLDER MASK
DEFINED
SOLDER MASK DETAILS
4214989/A 12/2014
NOTES: (continued)
4. This package is designed to be soldered to a thermal pad on the board. For more information, see Texas Instruments literature
number SLUA271 (www.ti.com/lit/slua271).
www.ti.com
EXAMPLE STENCIL DESIGN
RTA0040A
WQFN - 0.8 mm max height
PLASTIC QUAD FLATPACK - NO LEAD
(1.48) TYP
9X ( 1.28)
31
40
40X (0.6)
1
30
40X (0.25)
36X (0.5)
(1.48)
TYP
SYMM
(5.8)
METAL
TYP
10
21
(R0.05) TYP
20
11
SYMM
(5.8)
SOLDER PASTE EXAMPLE
BASED ON 0.125 mm THICK STENCIL
EXPOSED PAD
70% PRINTED SOLDER COVERAGE BY AREA
SCALE:15X
4214989/A 12/2014
NOTES: (continued)
5. Laser cutting apertures with trapezoidal walls and rounded corners may offer better paste release. IPC-7525 may have alternate
design recommendations.
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