TI TFP101APZP

 PanelBus SLDS119C - MARCH 2000 − REVISED OCTOBER 2003
D Supports XGA Resolution
D
D
D
D
D
D Reduced Power Consumption − 1.8 V Core
(Output Pixel Rates Up to 86 MHz)
Digital Visual Interface (DVI) Specification
Compliant1
True-Color, 24 Bit/Pixel, 16.7M Colors at 1
or 2-Pixels Per Clock
Laser Trimmed Internal Termination
Resistors for Optimum Fixed Impedance
Matching
Skew Tolerant Up to One Pixel Clock Cycle
4x Over-Sampling
D
D
D
D
Operation With 3.3 V I/Os and Supplies2
Reduced Ground Bounce Using Time
Staggered Pixel Outputs
Lowest Noise and Best Power Dissipation
Using TI PowerPAD Packaging
Advanced Technology Using TI 0.18-µm
EPIC-5 CMOS Process
TFP101A Incorporates HSYNC Jitter
Immunity3
description
The Texas Instruments TFP101 and TFP101A are TI PanelBus flat panel display products, part of a
comprehensive family of end-to-end DVI 1.0 compliant solutions. Targeted primarily at desktop LCD monitors
and digital projectors, the TFP101/101A finds applications in any design requiring high-speed digital interface.
The TFP101/101A supports display resolutions up to XGA in 24-bit true color pixel format. The TFP101/101A
offers design flexibility to drive one or two pixels per clock, supports TFT or DSTN panels, and provides an option
for time staggered pixel outputs for reduced ground bounce.
PowerPAD advanced packaging technology results in best of class power dissipation, footprint, and ultra-low
ground inductance.
The TFP101/101A combines PanelBus circuit innovation with TI’s advanced 0.18-µm EPIC-5 CMOS
process technology, along with TI PowerPAD package technology to achieve a reliable, low-powered, low
noise, high-speed digital interface solution.
AVAILABLE OPTIONS
PACKAGED DEVICE
TA
100-TQFP
(PZP)
TFP101PZP
0°C to 70°C
TFP101APZP
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of
Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
1.
2.
3.
The Digital Visual Interface Specification, DVI, is an industry standard developed by the Digital Display Working Group (DDWG) for
high-speed digital connection to digital displays The TFP101 and TFP101A are compliant to the DVI Specification Rev. 1.0.
The TFP101/101A has an internal voltage regulator that provides the 1.8-V core power supply from the externally supplied 3.3-V
supplies.
The TFP101A incorporates additional circuitry to create a stable HSYNC from DVI transmitters that introduce undesirable jitter on
the transmitted HSYNC signal.
PanelBus, PowerPAD and EPIC-5 are trademarks of Texas Instruments.
I2C is a licensed bus protocol from Phillips Semiconductor, Inc.
Copyright  2000, Texas Instruments Incorporated
!" #$
# % & ## '($ # ) # "( "#
) "" $
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1
PanelBus SLDS119C - MARCH 2000 − REVISED OCTOBER 2003
OGND
QO23
OVDD
AGND
Rx2+
Rx2−
AVDD
AGND
AVDD
Rx1+
Rx1−
AGND
AVDD
AGND
Rx0+
Rx0−
AGND
RxC+
RxC−
AVDD
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
QO22
QO21
QO20
QO19
QO18
QO17
QO16
GND
DVDD
QO15
QO14
QO13
QO12
QO11
QO10
QO9
QO8
OGND
OVDD
QO7
QO6
QO5
QO4
QO3
QO2
100-PIN PACKAGE
(TOP VIEW)
RSVD
OCK_INV
99
100
50
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
DFO
PD
ST
PIXS
GND
DVDD
STAG
SCDT
PDO
QE0
QE1
QE2
QE3
QE4
QE5
QE6
QE7
OVDD
OGND
QE8
QE9
QE10
QE11
QE12
QE13
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
EXT_RES
PVDD
PGND
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
2
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
QO1
QO0
HSYNC
VSYNC
DE
OGND
ODCK
OVDD
CTL3
CTL2
CTL1
GND
DVDD
QE23
QE22
QE21
QE20
QE19
QE18
QE17
QE16
OVDD
OGND
QE15
QE14
PanelBus SLDS119C - MARCH 2000 − REVISED OCTOBER 2003
functional block diagram
3.3 V
3.3 V
1.8 V
Regulator
Internal 50-Ω
Termination
3.3 V
RED(0-7)
Rx2+
Rx2-
+
_
Channel 2
CH2(0-9)
Latch
CTL2
Channel 1
Rx1+
Rx1-
+
_
Latch
Rx0+
Rx0-
+
_
Latch
RxC+
RxC-
+
_
PLL
QE(0-23)
QO(0-23)
CTL3
Data Recovery CH1(0-9)
TMDS
and
Decoder
Synchronization
Channel 0
CH0(0-9)
GRN(0-7)
CTL1
BLU(0-7)
VSYNC
HSYNC
Panel
Interface
ODCK
DE
SCDT
CTL3
CTL2
CTL1
VSYNC
HSYNC
Terminal Functions
TERMINAL
NAME
NO.
I/O
DESCRIPTION
AGND
79,83,87,
89,92
GND
Analog Ground – Ground reference and current return for analog circuitry.
AVDD
82,84,88,
95
VDD
Analog VDD – Power supply for analog circuitry. Nominally 3.3 V
CTL[3:1]
42,41,40
DO
General-purpose control signals – Used for user defined control. CTL1 is not powered-down via PDO.
46
DO
Output data enable – Used to indicate time of active video display versus non-active display or blank time.
During blank, only HSYNC, VSYNC, and CTL1-3 are transmitted. During times of active display, or non-blank,
only pixel data, QE[23:0] and QO[23:0], is transmitted.
DE
High : Active display time
Low: Blank time
DFO
1
DI
Output clock data format – Controls the output clock (ODCK) format for either TFT or DSTN panel support. For
TFT support ODCK clock runs continuously. For DSTN support ODCK only clocks when DE is high, otherwise
ODCK is held low when DE is low.
High : DSTN support/ODCK held low when DE = low
Low: TFT support/ODCK runs continuously.
DGND
5,39,68
GND
Digital ground – Ground reference and current return for digital core
DVDD
6,38,67
Digital VDD – Power supply for digital core. Nominally 3.3 V
EXT_RES
96
VDD
AI
HSYNC
48
DO
Horizontal sync output
RSVD
99
DI
Reserved. Must be tied high for normal operation.
OVDD
18,29,43,
57,78
VDD
ODCK
44
DO
Internal impedance matching – The TFP101/101A is internally optimized for impedance matching at 50 Ω. An
external resistor tied to this pin will have no effect on device performance.
Output driver VDD – Power supply for output drivers. Nominally 3.3 V
Output data clock - Pixel clock. All pixel outputs QE[23:0] and QO[23:0] (if in 2-pixel/clock mode) along with
DE, HSYNC, VSYNC and CTL[3:1] are synchronized to this clock.
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PanelBus SLDS119C - MARCH 2000 − REVISED OCTOBER 2003
Terminal Functions (continued)
TERMINAL
NAME
OGND
OCK_INV
NO.
I/O
19,28,45,
58,76
GND
100
DI
DESCRIPTION
Output driver ground – Ground reference and current return for digital output drivers
ODCK Polarity – Selects ODCK edge on which pixel data (QE[23:0] and QO[23:0]) and control signals
(HSYNC, VSYNC, DE, CTL1-3 ) are latched
Normal Mode:
High : Latches output data on rising ODCK edge
Low : Latches output data on falling ODCK edge
PD
2
DI
Power down – An active low signal that controls the TFP101/101A power-down state. During power down all
output buffers are switched to a high impedance state. All analog circuits are powered down and all inputs are
disabled, except for PD.
If PD is left unconnected an internal pullup will default the TFP101/101A to normal operation.
High : Normal operation
Low: Power down
PDO
9
DI
Output drive power down – An active low signal that controls the power-down state of the output drivers.
During output drive power down, the output drivers (except SCDT and CTL1) are driven to a high impedance
state. When PDO is left unconnected, an internal pullup defaults the TFP101/101A to normal operation.
High : Normal operation/output drivers on
Low: Output drive power down.
PGND
98
GND
PIXS
4
DI
PLL GND – Ground reference and current return for internal PLL
Pixel select – Selects between one or two pixels per clock output modes. During the 2-pixel/clock mode, both
even pixels, QE[23:0], and odd pixels, QO[23:0], are output in tandem on a given clock cycle. During
1-pixel/clock, even and odd pixels are output sequentially, one at a time, with the even pixel first, on the even
pixel bus, QE[23:0]. (The first pixel per line is pixel-0, the even pixel. The second pixel per line is pixel-1, the
odd pixel.)
High : 2-pixel/clock
Low: 1-pixel/clock
PVDD
QE[0:7]
97
10-17
VDD
DO
PLL VDD – Power supply for internal PLL
Even blue pixel output – Output for even and odd blue pixels when in 1-pixel/clock mode. Output for even only
blue pixel when in 2-pixel per clock mode. Output data is synchronized to the output data clock, ODCK.
LSB: QE0/pin 10
MSB: QE7/pin 17
QE[8:15]
20-27
DO
Even green pixel output – Output for even and odd green pixels when in 1-pixel/clock mode. Output for even
only green pixel when in 2-pixel/clock mode. Output data is synchronized to the output data clock, ODCK.
LSB: QE8/pin 20
MSB: QE15/pin 27
QE[16:23]
30-37
DO
Even red pixel output – Output for even and odd red pixels when in 1-pixel/clock mode. Output for even only
red pixel when in 2-pixel/clock mode. Output data is synchronized to the output data clock, ODCK.
LSB: QE16/pin 30
MSB: QE23/pin 37
QO[0:7]
49-56
DO
Odd blue pixel output – Output for odd only blue pixel when in 2-pixel/clock mode. Not used, and held low,
when in 1-pixel/clock mode. Output data is synchronized to the output data clock, ODCK.
LSB: QO0/pin 49
MSB: QO7/pin 56
QO[8:15]
59-66
DO
Odd green pixel output – Output for odd only green pixel when in 2-pixel/clock mode. Not used, and held low,
when in 1-pixel/clock mode. Output data is synchronized to the output data clock, ODCK.
LSB: QO8/pin 59
MSB: QO15/pin 66
QO[16:23]
69-75,77
DO
Odd red pixel output – Output for odd only red pixel when in 2-pixel/clock mode. Not used, and held low, when
in 1-pixel/clock mode. Output data is synchronized to the output data clock, ODCK.
LSB: QO16/pin 69
MSB: QO23/pin 77
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PanelBus SLDS119C - MARCH 2000 − REVISED OCTOBER 2003
Terminal Functions (continued)
TERMINAL
NAME
NO.
I/O
DESCRIPTION
RxC+
93
AI
Clock positive receiver input – Positive side of reference clock. TMDS low voltage signal differential input pair
RxC−
94
AI
Clock negative receiver input – Negative side of reference clock. TMDS low voltage signal differential input
pair.
Rx0+
90
AI
Channel-0 positive receiver input – Positive side of channel-0. TMDS low voltage signal differential input pair.
Channel-0 receives blue pixel data in active display and HSYNC, VSYNC control signals in blank.
Rx0−
91
AI
Channel-0 negative receiver input – Negative side of channel-0. TMDS low voltage signal differential input
pair.
Rx1+
85
AI
Channel-1 positive receiver input – Positive side of channel-1 TMDS low voltage signal differential input pair.
Channel-1 receives green pixel data in active display and CTL1 control signals in blank.
Rx1−
86
AI
Channel-1 negative receiver input – Negative side of channel-1 TMDS low voltage signal differential input pair
Rx2+
80
AI
Channel-2 positive receiver input – Positive side of channel-2 TMDS low voltage signal differential input pair.
Channel-2 receives red pixel data in active display and CTL2, CTL3 control signals in blank.
Rx2−
81
AI
Channel-2 negative receiver input – Negative side of channel-2 TMDS low voltage signal differential input pair.
SCDT
8
DO
Sync detect – Output to signal when the link is active or inactive. The link is considered to be active when DE is
actively switching. The TFP101/101A monitors the state DE to determine link activity. SCDT can be tied
externally to PDO to power down the output drivers when the link is inactive.
High: Active link
Low: Inactive link
ST
3
DI
Output drive strength select – Selects output drive strength for high or low current drive. (See dc specifications
for IOH and IOL vs ST state.)
High : High drive strength
Low : Low drive strength
STAG
7
DI
Staggered pixel select – An active low signal used in the 2-pixel/clock pixel mode (PIXS = high). Time staggers
the even and odd pixel outputs to reduce ground bounce. Normal operation outputs the odd and even pixels
simultaneously.
High : Normal simultaneous even/odd pixel output
Low: Time staggered even/odd pixel output
VSYNC
47
DO
Vertical sync output
absolute maximum ratings over operating free-air temperature (unless otherwise noted)†
Supply voltage range, DVDD, AVDD, OVDD, PVDD . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.3 V to 4 V
Input voltage range, logic/analog signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.3 V to 4 V
Operating ambient temperature range . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0°C to 70°C
Storage temperature range . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . - 65°C to 150°C
Case temperature for 10 seconds . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 260°C
Lead temperature 1,6 mm (1/16 inch) from case for 10 seconds . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 260°C
Package power dissipation/PowerPAD: Soldered (see Note 1) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.3 W
Not soldered (see Note 2) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.7 W
ESD Protection, all pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.5 KV Human Body Model
JEDEC latchup (EIA/JESD78) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100 mA
† Stresses beyond those listed under “absolute maximum ratings” may cause permanent damage to the device. These are stress ratings only, and
functional operation of the device at these or any other conditions beyond those indicated under “recommended operating conditions” is not
implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
NOTES: 1. Specified with PowerPAD bond pad on the backside of the package soldered to a 2 oz. Cu plate PCB thermal plane. Specified
at maximum allowed operating temperature, 70°C.
2. PowerPAD bond pad on the backside of the package is not soldered to a thermal plane. Specified at maximum allowed operating
temperature, 70°C.
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PanelBus SLDS119C - MARCH 2000 − REVISED OCTOBER 2003
recommended operating conditions
Supply voltage, VDD (DVDD, AVDD, PVDD, OVDD)
Pixel time, tpix†
MIN
TYP
MAX
3
3.3
3.6
V
40
ns
55
Ω
11.6
Single ended analog input termination resistance, Rt
45
50
UNIT
Operating free-air temperature, TA
0
25
70
°C
† tpix is the pixel time defined as the period of the RxC clock input. The period of the output clock, ODCK is equal to tpix when in 1-pixel/clock mode
and 2tpix when in 2-pixel/clock mode.
electrical characteristics over recommended operating free-air temperature range (unless
otherwise noted)
dc digital I/O specifications
PARAMETER
VIH
VIL
TEST CONDITIONS
MIN
High level digital input voltage‡
Low level digital input voltage‡
IOH
High level output drive current§
IOL
Low level output drive current§
TYP
2
0
ST = High,
ST = Low,
ST = High,
ST = Low,
MAX
V
0.8
V
VOH = 2.4 V
VOH = 2.4 V
5
10
14
3
6
9
VOL = 0.8 V
VOL = 0.8 V
10
13
19
5
7
11
IOZ
Hi-Z output leakage current
PD = Low or PDO = Low
‡ Digital inputs are labeled DI in I/O column of Terminal Functions Table.
§ Digital outputs are labeled DO in I/O column of Terminal Functions Table.
UNIT
DVDD
-1
1
mA
mA
µA
dc specifications
PARAMETER
TEST CONDITIONS
VID
VIC
Analog input differential voltage (see Note 3)
VI(OC)
Open circuit analog input voltage
IDD(2PIX)
Normal 2-pix/clock power supply current (see Note 4)
ODCK = 43 MHz
2-pix/clock
IPD
Power down current (see Note 5)
PD = Low
Output drive power down current (see Note 5)
PDO = Low
IPDO
NOTES: 3.
4.
5.
6
Analog input common mode voltage (see Note 3)
MIN
TYP
• DALLAS, TEXAS 75265
UNIT
1200
mv
AVDD-300
AVDD-10
AVDD-37
AVDD+10
mv
350
mA
10
mA
35
Specified as dc characteristic with no overshoot or undershoot.
Alternating 2-pixel black/2-pixel white pattern. ST = high, STAG = high, QE[23:0] and QO[23:0] CL = 10 pF.
Analog inputs are open circuit (transmitter is disconnected from TFP101/101A).
POST OFFICE BOX 655303
MAX
75
mv
mA
PanelBus SLDS119C - MARCH 2000 − REVISED OCTOBER 2003
electrical characteristics over recommended operating free-air temperature range (unless
otherwise noted) (continued)
ac specifications
VID(2)
tps
PARAMETER
Differential input sensitivity†
TEST CONDITIONS
MIN
TYP
150
Analog input intra-pair (+ to -) differential skew (see Note 6)
MAX
UNIT
1560
mVp-p
tbit‡
0.4
tccs
Analog Input inter-pair or channel-to-channel skew
(see Note 6)
tijit
Worse case differential input clock jitter tolerance¶
(see Note 6)
tf1
Fall time of data and control signals#, ||
ST = Low,
ST = High,
CL=5 pF
CL=10 pF
2.4
1.9
ns
tr1
Rise time of data and control signals#, ||
ST = Low,
ST = High,
CL=5 pF
CL=10 pF
2.4
1.9
ns
tr2
Rise time of ODCK clock#
ST = Low,
ST = High,
CL=5 pF
CL=10 pF
2.4
1.9
ns
tf2
Fall time of ODCK clock#
ST = Low,
ST = High,
CL=5 pF
CL=10 pF
2.4
1.9
ns
tsu1
Setup time, data and control signal to falling edge of ODCK
(OCK_INV = low)||
ST = Low,
ST = High,
CL=5 pF
CL=10 pF
3.6
ns
th1
Hold time, data and control signal to falling edge of ODCK
(OCK_INV = low)||
ST = Low,
ST = High,
CL=5 pF
CL=10 pF
3.6
ns
tsu2
Setup time, data and control signal to rising edge of ODCK
(OCK_INV = high)||
ST = Low,
ST = High,
CL=5 pF
CL=10 pF
3.6
ns
th2
Hold time, data and control signal to rising edge of ODCK
(OCK_INV = high)||
ST = Low,
ST = High,
CL=5 pF
CL=10 pF
3.1
ns
fODCK
ODCK frequency
1
50
tt(HSC)
tt(FSC)
td(st)
ps
PIX = Low (1-PIX/CLK)
25
86
PIX = High (2-PIX/CLK)
12.5
43
ODCK duty-cycle
tpd(PDL)
tpd(PDOL)
40%
tpix§
50%
MHz
60%
Propagation delay time from PD low to Hi-Z outputs
9
ns
Propagation delay time from PDO low to Hi-Z outputs
Transition time between DE transition to SCDT lowk
9
ns
1e6
Transition time between DE transition to SCDT highk
1024
tpix
tpix
0.25
tpix
Delay time, ODCK latching edge to QE[23:0] data output
STAG = Low
Pixs = High
† Specified as ac parameter to include sensitivity to overshoot, undershoot and reflection.
‡ tbit is 1/10 the pixel time, tpix
§ tpix is the pixel time defined as the period of the RxC input clock. The period of ODCK is equal to tpix in 1-pixel/clock mode or 2tpix when in
2-pixel/clock mode.
¶ Measured differentially at 50% crossing using ODCK output clock as trigger.
# Rise and fall times measured as time between 20% and 80% of signal amplitude.
|| Data and control signals are : QE[23:0], QO[23:0], DE, HSYNC, VSYNC and CTL[3:1]
k Link active or inactive is determined by amount of time detected between DE transitions. SCDT indicates link activity.
NOTE 6: By characterization
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PanelBus SLDS119C - MARCH 2000 − REVISED OCTOBER 2003
PARAMETER MEASUREMENT INFORMATION
tr1
tf1
80%
QE(0-23), QO(0-23), DE
CTK(1-3), HSYNC, VSYNC
80%
20%
20%
Figure 1. Rise and Fall TIme of Data and Control Signals
tr2
tf2
80%
ODCK
80%
20%
20%
Figure 2. Rise and Fall Time of ODCK
fODCK
ODCK
Figure 3. ODCK Frequency
t(su1)
t(su2)
t(h1)
ODCK
QE(0-23), QO(0-23), DE
CTL(1-3), HSYNC, VSYNC
t(h2)
VOH
VOL
VOH
VOL
VOH
VOL
VOH
VOL
VOH
VOL
VOH
VOL
OCK_INV
Figure 4. Data Setup and Hold Time to Rising and Falling Edge of ODCK
VOH
ODCK
tps
td(st)
Tx+
50%
QE(O-23)
50%
Tx-
Figure 5. ODCK High to QE[23:0]
Staggered Data Output
8
POST OFFICE BOX 655303
Figure 6. Analog Input Intra-Pair
Differential Skew
• DALLAS, TEXAS 75265
PanelBus SLDS119C - MARCH 2000 − REVISED OCTOBER 2003
PARAMETER MEASUREMENT INFORMATION
PD
PDO
VIL
VIL
tpd(PDL)
tpd(PDOL)
QE(0-23), QO(0-23),
ODCK, DE, CTL(1-3),
HSYNC, VSYNC, SCDT
QE(0-23), QO(0-23),
ODCK, DE, CTL(2-3),
HSYNC, VSYNC
Figure 7. Delay From PD Low to Hi-Z Outputs
Figure 8. Delay From PDO Low to Hi-Z Outputs
VIH
PD
twL(PDL_MIN)
tp(PDH-V)
DFO, ST, PIXS, STAG,
Rx(0-2)+, Rx(0-2)-,
OCK_INV
PD
Figure 9. Delay From PD Low to High Before
Inputs are Active
TX2
VIL
Figure 10. Minimum Time PD Low
50%
TX1
tccs
TX0
50%
Figure 11. Analog Input Channel-to-Channel Skew
tt(HSC)
tt(FSC)
DE
SCDT
Figure 12. Time Between DE Transitions to SCDT Low and SCDT High
tDEL
tDEH
DE
Figure 13. Minimum DE Low and Maximum DE High
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PanelBus SLDS119C - MARCH 2000 − REVISED OCTOBER 2003
detailed description
fundamental operation
The TFP101/101A is a digital visual interface (DVI) compliant TMDS digital receiver that is used in digital flat
panel display systems to receive and decode TMDS encoded RGB pixel data streams. In a digital display
system a host, usually a PC or workstation, contains a TMDS compatible transmitter that receives 24 bit pixel
data along with appropriate control signals and encodes them into a high-speed low-voltage differential serial
bit stream fit for transmission over a twisted-pair cable to a display device. The display device, usually a
flat-panel monitor, will require a TMDS compatible receiver like the TI TFP101/101A to decode the serial bit
stream back to the same 24 bit pixel data and control signals that originated at the host. This decoded data can
then be applied directly to the flat panel drive circuitry to produce an image on the display. Since the host and
display can be separated by distances up to 5 meters or more, serial transmission of the pixel data is preferred.
To support modern display resolutions up to SXGA a high bandwidth receiver with good jitter and skew tolerance
is required.
TMDS pixel data and control signal encoding
TMDS stands for transition minimized differential signaling. Only one of two possible TMDS characters for a
given pixel will be transmitted at a given time. The transmitter keeps a running count of the number of ones and
zeros previously sent and transmits the character that will minimize the number of transitions and approximate
a dc balance of the transmission line.
Three TMDS channels are used to receive RGB pixel data during active display time, DE = high. The same three
channels also receive control signals, HSYNC, VSYNC, and user defined control signals CTL[3:1]. These
control signals are received during inactive display or blanking-time. Blanking-time is when DE = low. The
following table maps the received input data to appropriate TMDS input channel in a DVI compliant system.
RECEIVED PIXEL DATA
ACTIVE DISPLAY DE = HIGH
INPUT CHANNEL
OUTPUT PINS
(VALID FOR DE = HIGH)
Red[7:0]
Channel – 2 (Rx2 ±)
QE[23:16] QO[23:16]
Green[7:0]
Channel – 1 (Rx1 ±)
QE[15:8] QO[15:8]
Blue[7:0]
Channel – 0 (Rx0 ±)
QE[7:0] QO[7:0]
RECEIVED CONTROL DATA
BLANKING DE = LOW
INPUT CHANNEL
OUTPUT PINS
(VALID FOR DE = LOW)
CTL[3:2]
Channel – 2 (Rx2 ±)
CTL[3:2]
CTL[1: 0] (see Note 6)
Channel – 1 (Rx1 ±)
CTL1
HSYNC, VSYNC
Channel – 0 (Rx0 ±)
HSYNC, VSYNC
NOTE 7: Some TMDS transmitters transmit a CTL0 signal. The TFP101/101A decodes and
transfers CTL[3:1] and ignores CTL0 characters. CTL0 is not available as a
TFP101/101A output.
The TFP101/101A discriminates between valid pixel TMDS characters and control TMDS characters to
determine the state of active display versus blanking, i.e., state of DE.
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detailed description (continued)
TFP101/101A clocking and data synchronization
The TFP101/101A receives a clock reference from the DVI transmitter that has a period equal to the pixel time,
Tpix. The frequency of this clock is also referred to as the pixel rate. Since the TMDS encoded data on Rx[2:0]
contains 10 bits per 8 bit pixel it follows that the Rx[2:0] serial bit rate is 10 times the pixel rate. For example,
the required pixel rate to support an XGA resolution with 60 Hz refresh rate is 65 MHz. The TMDS serial bit rate
is 10x the pixel rate or 650 Mb/s. Due to the transmission of this high-speed digital bit stream, on three separate
channels (or twisted-pair wires) of long distances (3-5 meters), phase synchronization between the data steams
and the input reference clock is not guaranteed. In addition, skew between the three data channels is common.
The TFP101/101A uses a 4x oversampling scheme of the input data streams to achieve reliable synchronization
with up to 1-Tpix channel-to-channel skew tolerance. Accumulated jitter on the clock and data lines due to
reflections and external noise sources is also typical of high speed serial data transmission, hence the
TFP101/101A’s design for high jitter tolerance.
The input clock to the TFP101/101A is conditioned by a phase-locked-loop (PLL) to remove high frequency jitter
from the clock. The PLL provides four 10x clock outputs of different phase to locate and sync the TMDS data
streams (4x oversampling). During active display the pixel data is encoded to be transition minimized, whereas
in blank, the control data is encoded to be transition maximized. A DVI compliant transmitter is required to
transmit in blank for a minimum period of time, 128-Tpix, to ensure sufficient time for data synchronization when
the receiver sees a transition maximized code. Synchronization during blank, when the data is transition
maximized, ensures reliable data bit boundary detection. Phase synchronization to the data streams is unique
for each of the three input channels and is maintained as long as the link remains active.
TFP101/101A TMDS input levels and input impedance matching
The TMDS inputs to the TFP101/101A receiver have a fixed single-ended termination to AVDD The
TFP101/101A is internally optimized using a laser trim process to precisely fix the impedance at 50 Ω. The
device will function normally with or without a resistor on the EXT_RES pin, so it remains drop-in compatible
with current sockets. The fixed impedance eliminates the need for an external resistor while providing optimum
impedance matching to standard 50-Ω DVI cables.
Figure 14 shows a conceptual schematic of a DVI transmitter and TFP101/101A receiver connection. A
transmitter drives the twisted pair cable via a current source, usually achieved with an open drain type output
driver. The internal resistor, which is matched to the cable impedance, at the TFP101/101A input provides a
pullup to AVDD . Naturally, when the transmitter is disconnected and the TFP101/101A DVI inputs are left
unconnected, the TFP101/101A receiver inputs pullup to AVDD. The single ended differential signal and full
differential signal is shown in Figure 15. The TFP101/101A is designed to respond to differential signal swings
ranging from 150 mV to 1.56 V with common mode voltages ranging from (AVDD-300 mV) to (AVDD-37 mV).
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TFP101/101A TMDS input levels and input impedance matching (continued)
DVI
Transmitter
TI TFP101/101A
Receiver
AVDD
DVI Compliant Cable
Internal
Termination at 50 Ω
DATA
DATA
+
_
Current
Source
Figure 14. TMDS Differential Input and Transmitter Connection
VIDIFF
+ 1/2 VIDIFF
1/2 VIDIFF
AVCC
AVCC - 1/2 VIDIFF
- 1/2 VIDIFF
b) Differential Input Signal
a ) Single-Ended Input Signal
Figure 15. TMDS Inputs
TFP101A incorporates HSYNC jitter immunity
Several DVI transmitters available in the market introduce jitter on the transmitted HSYNC and VSYNC signals
during the TMDS encryption process. The HSYNC signal can shift by one pixel position (one clock) from nominal
in either direction, resulting in up to two cycles of HSYNC shift. This jitter carries through to the DVI receiver,
and if the position of HSYNC shifts continuously, the receiver can lose track of the input timing and pixel noise
will occur on the display. For this reason, a DVI compliant receiver with HSYNC jitter immunity should be used
in all displays that could be connected to host PCs with transmitters that have this HSYNC jitter problem.
The TFP101A integrates HSYNC regeneration circuitry that provides a seamless interface to these
noncompliant transmitters. The position of the data enable (DE) signal is always fixed in relation to data,
irrespective of the location of HSYNC. The TFP101A receiver uses the DE and clock signals recreate stable
vertical and horizontal sync signals. The circuit filters the HSYNC output of the receiver, and HSYNC is shifted
to the nearest eighth bit boundary, producing a stable output with respect to data, as shown in Figure 16. This
will ensure accurate data synchronization at the input of the display timing controller.
This HSYNC regeneration circuit is transparent to the monitor and need not be removed even if the transmitted
HSYNC is stable. For example, the PanelBus line of DVI 1.0 compliant transmitters, such as the TFP6422 and
TFP420, do not have the HSYNC jitter problem. The TFP101A will operate correctly with either compliant or
noncompliant transmitters. In contrast, the TFP101 is ideal for customers who have control over the transmit
portion of the design such as bundled system manufacturers and for internal monitor use (the DVI connection
between monitor and panel modules).
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TFP101A incorporates HSYNC jitter immunity (continued
ODCK
HSYNC Shift by ± 1 Clock
HSYNC IN
DE
HSYNC OUT
Figure 16. HSYNC Regeneration Timing Diagram
TFP101/101A modes of operation
The TFP101/101A provides systems design flexibility and value by providing the system designer with
configurable options or modes of operation to support varying system architectures. The following table outlines
the various panel modes that can be supported along with appropriate external control pin settings.
PIXEL RATE
ODCK LATCH
EDGE
ODCK
DFO
PIXS
OCK_INV
TFT or 16-bit DSTN
1 pix/clock
Falling
Free run
0
0
0
TFT or 16-bit DSTN
1 pix/clock
Rising
Free run
0
0
1
TFT
2 pix/clock
Falling
Free run
0
1
0
TFT
2 pix/clock
Rising
Free run
0
1
1
24-bit DSTN
1 pix/clock
Falling
Gated low
1
0
0
NONE
1 pix/clock
Rising
Gated low
1
0
1
24-bit DSTN
2 pix/clock
Falling
Gated low
1
1
0
24-bit DSTN
2 pix/clock
Rising
Gated low
1
1
1
PANEL
TFP101/101A output driver configurations
The TFP101/101A provides flexibility by offering various output driver features that can be used to optimize
power consumption, ground-bounce and power-supply noise. The following sections outline the output driver
features and their effects.
Output driver power down (PDO = low), Pulling PDO low will place all the output drivers, except CTL1 and
SCDT, into a high-impedance state. The SCDT output which indicates link-disabled or link-inactive can be tied
directly to the PDO input to disable the output drivers when the link is inactive or when the cable is disconnected.
An internal pullup on the PDO pin will default the TFP101/101A to the normal nonpower down output drive mode
if left unconnected.
Drive Strength (ST = high for high drive strength, ST=low for low drive strength.) The TFP101/101A allows
for selectable output drive strength on the data, control and ODCK outputs. See the dc specifications table for
the values of IOH and IOL current drives for a given ST state. The high output strength offers approximately two
times the drive as the low output drive strength.
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TFP101/101A output driver configurations (continued)
Time Staggered Pixel Output. This option works only in conjunction with the 2-pixel/clock mode (PIXS = high).
Setting STAG = low will time stagger the even and odd pixel output so as to reduce the amount of instantaneous
current surge from the power supply. Depending on the PCB layout and design this can help reduce the amount
of system ground bounce and power supply noise. The time stagger is such that in 2-pixel/clock mode the even
pixel is delayed from the latching edge of ODCK by 0.25 Tcip. (Tcip is the period of ODCK. The ODCK period
is 2Tpix when in 2-pixel/clock mode.)
Depending on system constraints of output load, pixel rate, panel input architecture and board cost the
TFP101/101A drive strength and staggered pixel options allow flexibility to reduce system power-supply noise,
ground bounce and EMI.
Power Management. The TFP101/101A offers several system power management features.
The output driver power down (PDO = low) is an intermediate mode which offers several uses. During this mode,
all output drivers except SCDT and CTL1 are driven to a high impedance state while the rest of the device
circuitry remains active
The TFP101/101A power down (PD = low) is a complete power down in that it powers down the digital core,
the analog circuitry, and output drivers. All output drivers are placed into a Hi-z state. All inputs are disabled
except for the PD input. The TFP101/101A will not respond to any digital or analog inputs until PD is pulled high.
Both PDO and PD have internal pullups so if left unconnected they will default the TFP101/101A to normal
operating modes.
Sync Detect. The TFP101/101A offers an output, SCDT to indicate link activity. The TFP101/101A monitors
activity on DE to determine if the link is active. When 1 million (1e6) pixel clock periods pass without a transition
on DE, the TFP101/101A considers the link inactive and SCDT is driven low. While SCDT is low, if two DE
transitions are detected within 1024 pixel clock periods, the link will be considered active and SCDT is pulled
high.
SCDT can be used to signal a system power management circuit to initiate a system power down when the link
is considered inactive. The SCDT can also be tied directly to the TFP101/101A PDO input to power down the
output drivers when the link is inactive. It is not recommended to use the SCDT to drive the PD input since, once
in complete power-down, the analog inputs are ignored and the SCDT state will not change. An external system
power management circuit to drive PD is preferred.
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TI PowerPAD 100-TQFP package
The TFP101/101A is packaged in TI’s thermally enhanced PowerPAD 100TQFP packaging. The PowerPAD
package is a 14 mm × 14 mm × 1 mm TQFP outline with 0.5mm lead-pitch. The PowerPAD package has a
specially designed die mount pad that offers improved thermal capability over typical TQFP packages of the
same outline. The TI 100-TQFP PowerPAD package offers a back-side solder plane that connects directly
to the die mount pad for enhanced thermal conduction. Soldering the back side of the TFP101/101A to the
application board is not required thermally as the device power dissipation is well within the package capability
when not soldered.
Soldering the back side of the device to the PCB ground plane is recommended for elctrical considerations.
Since the die pad is electrically connected to the chip substrate and hence chip ground, connection of the
PowerPAD back side to a PCB ground plane will help to improve EMI, ground bounce, and power supply noise
performance.
Table 1 outlines the thermal properties of the TI 100-TQFP PowerPAD package. The 100-TQFP nonPowerPAD package is included only for reference.
Table 1. TI 100-TQFP (14 × 14 × 1 mm)/0.5 mm Lead Pitch
PARAMETER
Theta-JA†,‡
Theta-JC†,‡
WITHOUT
PowerPAD
PowerPAD
NOT CONNECTED TO PCB
THERMAL PLANE
PowerPAD
CONNECTED TO PCB
THERMAL PLANE†
45°C/W
27.3°C/W
17.3°C/W
3.11°C/W
0.12°C/W
0.12°C/W
2.7 W
4.3 W
Maximum power dissipation†,‡,§
1.6 W
† Specified with 2 oz. Cu PCB plating.
‡ Airflow is at 0 LFM (no airflow)
§ Measured at ambient temperature, TA = 70°C.
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THERMAL PAD MECHANICAL DATA
PowerPADt PLASTIC QUAD FLATPACK
PZP (S−PQFP−G100)
PPTD033
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