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7
PLL
TA +/-
TB +/-
TC +/-
TD +/-
TCLK +/-
R/F
/PDWN
TA0-6
TC0-6
TD0-6
TRANSMITTER
(8 to 160MHz)
CMOS/TTL
7
RS
7
TB0-6 7
INPUTS
CLOCK
(LVDS)
8-160MHz
DATA
(LVDS)
(56-1120Mbit/On Each
LVDS Channel)
CLKIN
THC63LVDM83D
CMOS/TTL PARALLEL
TO SERIAL
7
PLL
TA +/-
TB +/-
TC +/-
TD +/-
TCLK +/-
R/F
/PDWN
TA0-6
TC0-6
TD0-6
TRANSMITTER
(8 to 160MHz)
CMOS/TTL
7
RS
7
TB0-6 7
INPUTS
CLOCK
(LVDS)
8-160MHz
DATA
(LVDS)
(56-1120Mbit/On Each
LVDS Channel)
CLKIN
THC63LVDM83D
CMOS/TTL PARALLEL
TO SERIAL
THC63LVDM83D
24bit COLOR LVDS TRANSMITTER
General Description
The THC63LVDM83D transmitter is designed to support pixel
data transmission between Host and Flat Panel Display up to
1080p/WUXGA resolutions.
The THC63LVDM83D converts 28bits of LVCMOS data into
four OpenLDI(LVDS) data streams. The transmitter can be
programmed for rising edge or falling edge clock through a
dedicated pin. At a transmit clock frequency of 160MHz,
24bits of RGB data and 4bits of timing and control data
(HSYNC, VSYNC, DE, CONT1) are transmitted at an
effective rate of 1120Mbps per OpenLDI(LVDS) channel.
Application
・Medium and Small Size Panel
・Tablet PC / Notebook PC
・Security Camera / Industrial Camera
・Multi Function Printer
・Industrial Equipment
・Medical Equipment Monitor
Features
・Compatible with TIA/EIA-644 LVDS Standard
・7:1 OpenLDI(LVDS) Transmitter
・Operating Temperature Range : 0 to +70C
・No Special Start-up Sequence Required
・Spread Spectrum Clocking Tolerant up to 100kHz Frequency
Modulation and +/-2.5% Deviations.
・Wide Dot Clock Range: 8 to 160MHz Suited for
TV Signal : NTSC(12.27MHz) - 1080p(148.5MHz)
PC Signal : QVGA(8MHz) - WUXGA(154MHz)
・56pin TSSOP Package
・1.2V to 3.3V LVCMOS/ inputs are supported.
・LVDS swing is reducible as 200mV by RS-pin to reduce EMI
and power consumption.
・PLL requires no external components.
・Power Down Mode.
・Input clock triggering edge is selectable by R/F-pin
・EU RoHS Compliant.
Block Diagram
Figure 1. Block Diagram
THC63LVDM83D_Rev.4.30_E
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Pin Diagram
Figure 2. Pin Diagram
THC63LVDM83D_Rev.4.30_E
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Pin Description
Pin Name
Pin #
Direction
Type
Description
TA+, TA-
47, 48
Output
LVDS
LVDS Data Out
TB+, TB-
45, 46
TC+, TC-
41, 42
TD+, TD-
37, 38
TCLK+,
TCLK-
39, 40
LVDS Clock Out
TA0 ~ TA6
51, 52, 54, 55, 56, 3, 4
Input
LVCMOS
Pixel Data Input
TB0 ~ TB6
6, 7, 11, 12, 14, 15, 19
TC0 ~ TC6
20, 22, 23, 24, 27, 28,
30
TD0 ~ TD6
50, 2, 8, 10, 16, 18, 25
/PDWN
32
H : Normal Operation
L : Power Down (All outputs are Hi-Z)
RS
1
LVDS Swing Mode, VREF Select See Fig.7,
8
VREF : is Input Reference Voltage
R/F
17
Input Clock Triggering Edge Select
H : Rising Edge
L : Falling Edge
CLKIN
31
Input Clock
VCC
9, 26
Power
-
Power Supply Pins for LVCMOS inputs and
digital circuit.
GND
5, 13, 21, 29, 53
Ground Pins for LVCMOS Inputs and Digital
Circuitry.
LVDS VCC
44
Power Supply Pins for LVDS Outputs.
LVDS GND
36, 43 49
Ground Pins for LVDS Outputs.
PLL VCC
34
Power Supply Pin for PLL Circuitry.
PLL GND
33, 35
Ground Supply Pin for PLL Circuitry.
Table 1. Pin Description
RS Pin
LVDS
Swing
Small Swing
Input Support
VCC 350mV N/A
0.6 to 1.4V 350mV RS=VREF
GND 200mV N.A
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LVDS_OutP
LVDS_OutN
IN_N
IN_P
3.5mA
Absolute Maximum Ratings
Parameter
Min
Max
Unit
All Supply Voltage (VCC, LVDS VCC, PLL VCC)
-0.3
+4.0
V
LVCMOS Input Voltage
-0.3
VCC + 0.3
V
LVDS Output Pin
-0.3
VCC + 0.3
V
Output Current
-30
30
mA
Junction Temperature
-
+125
C
Storage Temperature
-55
+150
C
Reflow Peak Temperature
-
+260
C
Reflow Peak Temperature Time
-
10
sec
Maximum Power Dissipation @+25C
-
1.8
W
Table 2. Absolute Maximum Ratings
Recommended Operating Conditions
Symbol
Parameter
Min
Typ
Max
Unit
VCC, LVDS VCC
PLL VCC
All Supply Voltage
3.0
3.3
3.6
V
Ta
Operating Ambient Temperature
0
25
+70
C
-
Clock Frequency
8
-
160
MHz
Table 3. Recommended Operating Conditions
“Absolute Maximum Ratings” are those values beyond which the safety of the device can not be guaranteed.
They are not meant to imply that the device should be operated at these limits. The tables of “Electrical
Characteristics Table4, 5, 6, 7” specify conditions for device operation.
“Absolute Maximum Rating” value also includes behavior of overshooting and undershooting.
Equivalent LVDS Output Schematic Diagram
Figure 3. LVDS Output Schematic Diagram
THC63LVDM83D_Rev.4.30_E
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CLKIN
Tx0-6
Power Consumption
Over recommended operating supply and temperature range unless otherwise specified
Symbol
Parameter
Conditions
Typ*
Max
Unit
ITCCW
LVDS Transmitter
Operating Current
Worst Case Pattern
(Fig.4)
RL=100, CL=5pF, f=85MHz, RS=VCC
61
67
mA
RL=100, CL=5pF, f=135MHz,
RS=VCC
77
83
mA
RL=100, CL=5pF, f=160MHz,
RS=VCC
84
92
mA
RL=100, CL=5pF, f=85MHz, RS=GND
50
56
mA
RL=100, CL=5pF, f=135MHz,
RS=GND
65
71
mA
RL=100, CL=5pF, f=160MHz,
RS=GND
73
80
mA
ITCCS
LVDS Transmitter
Power Down Current
/PDWN=L, All Inputs=L or H
-
10
µA
*Typ values are at the conditions of VCC=3.3V and Ta = +25ºC
Table 4. Power Consumption
Worst Case Pattern
x=A,B,C,D Figure 4. Worst Case Pattern
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Electrical Characteristics
LVCMOS DC Specifications
Over recommended operating supply and temperature range unless otherwise specified
Symbol
Parameter
Conditions
Min
Typ*
Max
Unit
VIH
High Level Input Voltage
RS=VCC or GND
2.0
-
VCC
V
VIL
Low Level Input Voltage
RS=VCC or GND
GND
-
0.8
V
VDDQ1
Small Swing Voltage
1.2
-
2.8
V
VREF
Input Reference Voltage
Small Swing (RS=VDDQ/2)
-
VDDQ/2
-
VSH2
Small Swing High Level
Input Voltage
VREF= VDDQ/2
VDDQ/2
+100m
V
-
-
V
VSL2
Small Swing Low Level
Input Voltage
VREF= VDDQ/2
-
-
VDDQ/2
-100mV
V
IINC
Input Current
GND VIN VCC
-
-
10
A
*Typ values are at the conditions of VCC=3.3V and Ta = +25ºC
Notes : 1 VDDQ voltage defines the max voltage of small swing inputs at RS=VREF. It is not an actual input
voltage.
2 Small swing signals are applied to TA0-6, TB0-6, TC0-6, TD0-6 and CLKIN.
Table 5. LV-CMOS DC Specifications
LVDS Transmitter DC Specifications
Over recommended operating supply and temperature range unless otherwise specified
Symbol
Parameter
Conditions
Min
Typ*
Max
Unit
VOD
Differential Output Voltage
RL=100Ω
Normal swing
RS=VCC
250
350
450
mV
Reduced
swing
RS=GND
100
200
300
mV
∆VOD
Change in VOD between
complementary output
states
RL=100Ω
-
-
35
mV
VOC
Common Mode Voltage
1.125
1.25
1.375
V
∆VOC
Change in VOC between
complementary output
states
-
-
35
mV
IOS
Output Short Circuit
Current
VOUT=GND, RL=100Ω
-
-
-24
mA
IOZ
Output TRI-STATE
Current
/PDWN=GND,
VOUT=GND to VCC
-
-
10
A
*Typ values are at the conditions of VCC=3.3V and Ta = +25ºC
Table 6. LVDS Transmitter DC Specifications
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CLK IN
90%
10%
90%
10%
tTCIT tTCIT
VOC
VOD
50Ω
50Ω
5pF
Tn+
Tn-
0%
20%
80%
100%
0V
tLVT tLVT
VOD(H)
VOD(L)
LVCMOS & LVDS Transmitter AC Specifications
Over recommended operating supply and temperature range unless otherwise specified
Symbol
Parameter
Min
Typ
Max
Unit
tTCIT
CLK IN Transition Time
-
-
5.0
ns
tTCP
CLK IN Period
6.25
T
125
ns
tTCH
CLK IN High Time
0.35T
0.5T
0.65T
ns
tTCL
CLK IN Low Time
0.35T
0.5T
0.65T
ns
tTCD
CLK IN to TCLK+/- Delay
-
3T
-
ns
tTS
LVCMOS Data Setup to CLK IN
2.0
-
-
ns
tTH
LVCMOS Data Hold from CLK IN
0.0
-
-
ns
tLVT
LVDS Transition Time
-
0.6
1.5
ns
tTOP1
Output Data Position0 (T=6.25ns ~ 20ns)
-0.15
0.0
+0.15
ns
tTop0
Output Data Position1 (T=6.25ns ~ 20ns)
T/7-0.15
T/7
T/7+0.15
ns
tTop6
Output Data Position2 (T=6.25ns ~ 20ns)
2T/7-0.15
2T/7
2T/7+0.15
ns
tTop5
Output Data Position3 (T=6.25ns ~ 20ns)
3T/7-0.15
3T/7
3T/7+0.15
ns
tTop4
Output Data Position4 (T=6.25ns ~ 20ns)
4T/7-0.15
4T/7
4T/7+0.15
ns
tTop3
Output Data Position5 (T=6.25ns ~ 20ns)
5T/7-0.15
5T/7
5T/7+0.15
ns
tTop2
Output Data Position6 (T=6.25ns ~ 20ns)
6T/7-0.15
6T/7
6T/7+0.15
ns
tTPLL
Phase Lock Loop Set
-
-
10.0
ms
*Typ values are at the conditions of VCC=3.3V and Ta = +25ºC
Table 7. LVCMOS & LVDS Transmitter AC Specifications
LVCMOS Input
Figure 5. CLKIN Transmission Time
LVDS Output
LVDS Output Load
Figure 6. LVDS Output Load and Transmission Time
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RS
VOD
VCC
0.6 ~ 1.4V
GND 200mV
350mV
RS
VREF
VCC ---
0.6 ~ 1.4V
VDDQ/2
GND ---
AC Timing Diagrams
LVCMOS Inputs
Normal Swing Input
Note :
CLKIN : Solid line denotes the setting of R/F=GND
Dashed line denotes the setting of R/F = VCC
Figure 7. LVCOMS Inputs and LVDS Clock Output Timing 1
Small Swing Inputs
Note :
CLKIN : Solid line denotes the setting of R/F=GND
Dashed line denotes the setting of R/F = VCC
Figure 8. LVCMOS Inputs and LVDS Output Timing 2
tTCP
tTS tTH
tTCH
tTCL
CLKIN
Tx0-Tx6
tTCD
TCLK+
TCLK-
VCC
GND
GND
VCC
VOC
VCC/2 VCC/2 VCC/2
VCC/2 VCC/2
tTCP
tTS tTH
tTCH
tTCL
CLKIN
Tx0-Tx6
tTCD
TCLK+
TCLK-
VDDQ
GND
GND
VDDQ
VREF
VOC
VREF
VDDQ/2 VDDQ/2
VDDQ/2 VDDQ/2 VDDQ/2
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Vdiff = 0V Vdiff = 0V
TCLK+/-
tTOP1tTOP0
tTOP6
tTOP5
tTOP4
tTOP3
tTOP2
TD6 TD5 TD4 TD3 TD2 TD1 TD0
TD+/-
TC6 TC5 TC4 TC3 TC2 TC1 TC0TC+/-
TB6 TB5 TB4 TB3 TB2 TB1 TB0TB+/-
TA6 TA5 TA4 TA3 TA2 TA1 TA0TA+/-
(Differential)
Next Cycle
Previous Cycle
2.0V
CLKIN
/PDWN
TCLK+/-
3.0V
VCC tTPLL
Vdiff = 0V
LVDS Output Data Position
Figure 9. LVDS Output Data Position
Phase Lock Loop Set Time
Figure 10. PLL Lock Loop Set Time
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Spread Spectrum Clocking Tolerant
Figure 11. Spread Spectrum Clocking Tolerant
The graph indicates the range that the IC works normally under SS clock input operation.
The results are measured with a typical sample on condition of +25Cº and 3.3V, therefore these
values are for reference and do not guarantee the performance of a product under other
circumstance.
LVDS Data Timing Diagram
Figure 12. LVDS Data Timing Diagram
Vdiff=0V Vdiff=0V
TCLK+/-
(Differntial)
Tx+/-
X=A,B,C,D
Previous Pixel Data Pixel Data
Tx6 Tx5 Tx4 Tx3 Tx2 Tx1 Tx0
THC63LVDM83D_Rev.4.30_E
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For Display Application
THC63LVDM83D Pixel Data Mapping for JEIDA Format (6bit, 8bit Application)
Note : Use TA to TC channels and open TD channel for 6bit application.
Table 8. Data Mapping for JEIDA Format
6bit
8bit
TA0
R2
R2
TA1
R3
R3
TA2
R4
R4
TA3
R5
R5
TA4
R6
R6
TA5
R7
R7
TA6
G2
G2
TB0
G3
G3
TB1
G4
G4
TB2
G5
G5
TB3
G6
G6
TB4
G7
G7
TB5
B2
B2
TB6
B3
B3
TC0
B4
B4
TC1
B5
B5
TC2
B6
B6
TC3
B7
B7
TC4
Hsync
Hsync
TC5
Vsync
Vsync
TC6
DE
DE
TD0
-
R0
TD1
-
R1
TD2
-
G0
TD3
-
G1
TD4
-
B0
TD5
-
B1
TD6
-
N/A
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THC63LVDM83D Pixel Data Mapping for VESA Format (6bit, 8bit Application)
Note : Use TA to TC channels and open TD channel for 6bit application.
Table 9. Data Mapping for VESA Format
6bit
8bit
TA0
R0
R0
TA1
R1
R1
TA2
R2
R2
TA3
R3
R3
TA4
R4
R4
TA5
R5
R5
TA6
G0
G0
TB0
G1
G1
TB1
G2
G2
TB2
G3
G3
TB3
G4
G4
TB4
G5
G5
TB5
B0
B0
TB6
B1
B1
TC0
B2
B2
TC1
B3
B3
TC2
B4
B4
TC3
B5
B5
TC4
Hsync
Hsync
TC5
Vsync
Vsync
TC6
DE
DE
TD0
-
R6
TD1
-
R7
TD2
-
G6
TD3
-
G7
TD4
-
B6
TD5
-
B7
TD6
-
N/A
THC63LVDM83D_Rev.4.30_E
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Typical Connection
Figure 13. Typical Connection Diagram
THC63LVDM83D_Rev.4.30_E
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Notes
1) Cable Connection and Disconnection
Do not connect and disconnect the LVDS cable, when the power is supplied to the system.
2) GND Connection
Connect each GND of the PCB which THC63LVDM83D and LVDS-Rx on it. It is better for EMI
reduction to place GND cable as close to LVDS cable as possible.
3) Multi Drop Connection
Multi drop connection is not recommended.
Figure 14. Multi Drop Connection
4) Asynchronous use
Asynchronous using such as following systems is not recommended.
Figure 15. Asynchronous Use
LVDS-RX
THC63LVDM83D
LVDS-RX
TCLK+
TCLK-
IC
CLKOUT
CLKOUT
DATA
DATA
LVDS-RX
LVDS-RX
IC
TCLK+
TCLK-
TCLK+
TCLK-
CLKOUT
DATA
DATA
THC63LVDM83D
THC63LVDM83D
IC
TCLK+
TCLK-
TCLK+
TCLK-
CLKOUT
CLKOUT
DATA
DATA
IC
THC63LVDM83D
THC63LVDM83D
THC63LVDM83D_Rev.4.30_E
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1.00REF
0.60+/-0.15
0.25
GAUGE PLANE
0.5
0.17~0.27
14.00+/-0.10
S
0.10 S
6.10+/-0.1
8.10 NOM
0.05~0.15 1.20MAX
SEATING PLANE
UNIT:mm
Package
Figure 16. Package Diagram
THC63LVDM83D_Rev.4.30_E
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CY1=
HE=e=
E=
Ttyp.=
Gmin= b=
Zmax= Xmax=
Zmax/2
5. 50
9. 30
0.60
8.100
6.10
10.34
0.500
1. 90
0.200
0.470
Unit mm
Package
Land Pattern
Reference Land Pattern
Figure 17. Reference of Land Pattern
The recommendation mounting method of THine device is reflow soldering.
The reference pattern is using the calculation result on condition of reflow soldering.
Notes
This land pattern design is a calculated value based on JEITA ET-7501.
Please take into consideration in an actual substrate design about enough the ease of mounting, the intensity of
connection, the density of mounting, and the solder paste used, etc… The optimal land pattern size changes
with these parameters. Please use the value shown by the land pattern as reference data.
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Notices and Requests
1. The product specifications described in this material are subject to change without prior notice.
2. The circuit diagrams described in this material are examples of the application which may not always apply to
the customer's design. We are not responsible for possible errors and omissions in this material. Please note if
errors or omissions should be found in this material, we may not be able to correct them immediately.
3. This material contains our copyright, know-how or other proprietary. Copying or disclosing to third parties the
contents of this material without our prior permission is prohibited.
4. Note that if infringement of any third party's industrial ownership should occur by using this product, we will
be exempted from the responsibility unless it directly relates to the production process or functions of the
product.
5. Product Application
5.1 Application of this product is intended for and limited to the following applications: audio-video device,
office automation device, communication device, consumer electronics, smartphone, feature phone, and
amusement machine device. This product must not be used for applications that require extremely
high-reliability/safety such as aerospace device, traffic device, transportation device, nuclear power control
device, combustion chamber device, medical device related to critical care, or any kind of safety device.
5.2 This product is not intended to be used as an automotive part, unless the product is specified as a product
conforming to the demands and specifications of ISO/TS16949 ("the Specified Product") in this data sheet.
THine Electronics, Inc. (“THine”) accepts no liability whatsoever for any product other than the Specified
Product for it not conforming to the aforementioned demands and specifications.
5.3 THine accepts liability for demands and specifications of the Specified Product only to the extent that the
user and THine have been previously and explicitly agreed to each other.
6. Despite our utmost efforts to improve the quality and reliability of the product, faults will occur with a certain
small probability, which is inevitable to a semi-conductor product. Therefore, you are encouraged to have
sufficiently redundant or error preventive design applied to the use of the product so as not to have our
product cause any social or public damage.
7. Please note that this product is not designed to be radiation-proof.
8. Testing and other quality control techniques are used to this product to the extent THine deems necessary to
support warranty for performance of this product. Except where mandated by applicable law or deemed
necessary by THine based on the user’s request, testing of all functions and performance of the product is not
necessarily performed.
9. Customers are asked, if required, to judge by themselves if this product falls under the category of strategic
goods under the Foreign Exchange and Foreign Trade Control Law.
10. The product or peripheral parts may be damaged by a surge in voltage over the absolute maximum ratings or
malfunction, if pins of the product are shorted by such as foreign substance. The damages may cause a
smoking and ignition. Therefore, you are encouraged to implement safety measures by adding protection
devices, such as fuses.
THine Electronics, Inc.
sales@thine.co.jp
