THC63LVDR84C-B - CALIFORNIA EASTERN LABORATORIES

THC63LVDR84C_Rev.1.20_E

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THC63LVDR84C

24bit Color LVDS Receiver (Rising Edge Strobe Output)

General Description

The THC63LVDR84C receiver supports wide

temperature range as -40 to +85C, and wide

frequency range as 8 to 112MHz.

The THC63LVDR84C converts the four LVDS data

streams back into 24bits of LVCMOS data with

Rising edge clock. At a transmit clock frequency of

112MHz, 24bits of RGB data and 4bits of timing and

control data (HSYNC, VSYNC, DE, etc.) are

transmitted at an effective rate of 3.1Gbps.

Application

･Medium and Small Size Panel

･Security Camera

･Multi Function Printer

･Machine Vision (Frame Grabber Board)

･Medical Equipment Monitor

Features

･1:7 LVDS to LVCMOS Deserializer

･Operating Temperature Range : -40 to +85C

･No Special Start-up Sequence Required

･Spread Spectrum Clocking Tolerant up to 100kHz

Frequency Modulation and +/-2.5% Deviations

･Pixel Clock Range: 8 to 112MHz

･56pin TSSOP Package

･Power Down Mode

･Rising Edge Strobe Output

･EU RoHS Compliant

Recommended LVDS Transmitter ICs

･THC63LVDM83D

･THC63LVDM87

Block Diagram

PLL

RA +/-

RB +/-

RC +/-

RD +/-

/PDWN

7

LVDS Inputs

(56 to 784Mbps/ch)

RA0-6

CLKOUT

(8 to 112MHz)

LVCMOS Outputs

THC63LVDR84C

RB0-6

RC0-6

RD0-6

RCLK +/-

(8 to 112MHz)

7

LVDS to LVCMOS

1:7 Deserializer

Figure 1. Block Diagram

THC63LVDR84C_Rev.1.20_E

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Pin Diagram

1 56

2 55

3 54

4 53

5 52

6 51

7 50

8 49

9 48

10 47

11 46

12 45

13 44

14 43

15 42

16 41

17 40

18 39

19 38

20 37

21 36

22 35

23 34

24 33

25 32

26 31

27 30

28 29

RC3

RD6

RC4

GND

RC5

RC6

RD0

LVDS GND

RA-

RA+

RB-

RB+

LVDS VCC

LVDS GND

RC-

RC+

RCLK-

RCLK+

RD-

RD+

LVDS GND

PLL GND

PLL VCC

PLL GND

/PDWN

CLKOUT

RA0

GND

VCC

RC2

RC1

RC0

GND

RB6

RD5

RD4

VCC

RB5

RB4

RB3

GND

RB2

RD3

RD2

VCC

RB1

RB0

RA6

GND

RA5

RD1

RA4

RA3

VCC

RA2

RA1

Figure 2. Pin Diagram

Pin Description

Pin Name

Pin #

Direction

Type

Description

RA+, RA-

10, 9

Input

LVDS

LVDS Data Inputs

RB+, RB-

12, 11

RC+, RC-

16, 15

RD+, RD-

20, 19

RCLK+,

RCLK-

18, 17

LVDS Clock Inputs

RA0 ~ RA6

27, 29, 30, 32, 33, 35, 37

Output

LVCMOS

Pixel Data Outputs

RB0 ~ RB6

38, 39, 43, 45, 46, 47, 51

RC0 ~ RC6

53, 54, 55, 1, 3, 5, 6

RD0 ~ RD6

7, 34, 41, 42, 49, 50, 2

CLKOUT

26

Pixel Clock Output

/PDWN

25

Input

H : Normal Operation

L : Power Down (All outputs are pulled to

ground)

VCC

31, 40, 48, 56

-

Power

Power Supply Pins for LVCMOS outputs

and digital circuitry

GND

4, 28, 36, 44, 52

Ground Pins for LVCMOS outputs and

digital circuitry

LVDS VCC

13

Power Supply Pins for LVDS inputs

LVDS GND

8, 14, 21

Ground Pins for LVDS inputs

PLL VCC

23

Power Supply Pins for PLL circuitry

PLL GND

22, 24

Ground Pins for PLL circuitry

Table 1. Pin Description

THC63LVDR84C_Rev.1.20_E

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Absolute Maximum Ratings

Parameter

Min

Max

Unit

Supply Voltage (VCC, LVDS VCC, PLL VCC)

-0.3

+4.0

V

LVCMOS Input Voltage

-0.3

VCC + 0.3

V

LVCMOS Output Voltage

-0.3

VCC + 0.3

V

LVDS Input Pin

-0.3

VCC + 0.3

V

Junction Temperature

-

+125

C

Storage Temperature

-55

+150

C

Reflow Peak Temperature

-

+260

C

Reflow Peak Temperature Time

-

10

sec

Maximum Power Dissipation @+25C

-

1.9

W

Table 2. Absolute Maximum Ratings

Recommended Operating Conditions

Symbol

Parameter

Min

Typ

Max

Unit

VCC33

All Supply Voltage(VCC, LVDS VCC, PLL VCC)

3.0

-

3.6

V

Ta

Operating Ambient Temperature

-40

+25

+85

C

PCLK

RCLK and CLKOUT Clock Frequency

8

-

112

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.

THC63LVDR84C_Rev.1.20_E

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Equivalent LVDS Input Schematic Diagram

LVDS +

LVDS -

AMP

CMP

LVDS VCC

Output

Control

LVDS VCC

Figure 3. LVDS Input Schematic Diagram

Output Control

/PDWN

RCLK +/- Input

LVCMOS Output

H

Valid Clock

Active Clock & Data

H

Invalid Clock

Unfixed Clock & Data

H

Open or Hi-z

All Low

L

Don’t Care

All Low

Table 4. LVCMOS Output Data Control

THC63LVDR84C_Rev.1.20_E

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Power Consumption Over recommended operating supply and temperature range unless otherwise specified

Symbol

Parameter

Conditions

Typ*

Max

Unit

IRCCG

LVDS Receiver Operating Current

Gray Scale Pattern 16 (Fig.4)

CL=8pF, PCLK=65MHz,

VCC33=3.3V

55

70

mA

CL=8pF, PCLK=112MHz,

VCC33=3.3V

90

110

mA

IRCCW

LVDS Receiver Operating Current

Worst Case Pattern(Fig.5)

CL=8pF, PCLK=65MHz,

VCC33=3.3V

90

110

mA

CL=8pF, PCLK=112MHz,

VCC33=3.3V

130

160

mA

IRCCS

LVDS Receiver

Power Down Current

/PDWN=L

-

500

µA

*Typ values are at the conditions of Ta = +25ºC

Table 5. Power Consumption

16 Grayscale Pattern

CLKOUT

RA3, RB4, RC5

RA2, RB3, RC4

RA1, RB2, RC3

RA0, RB1, RC2

TA4-6, TB0/5/6

TC0/1/6, TD0-2

TD3-6

Steady State Low

Steady State High

Figure 4. 16 Grayscale Pattern

Worst Case Pattern

CLKOUT

Rx0-6

X=A,B,C,D

Figure 5. Worst Case Pattern

THC63LVDR84C_Rev.1.20_E

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Electrical Characteristics

LVDS Receiver DC Specifications

Over recommended operating supply and temperature range unless otherwise specified

Symbol

Parameter

Conditions

Min

Typ*

Max

Unit

VTH

Differential Input High

Threshold

RL=100Ω, VIC=+1.2V

-

100

mV

VTL

Differential Input Low

Threshold

-100

-

mV

IIN

Input Current

VIN=+2.4 / 0V

LVDS VCC=3.6V

-

30

A

Table 6. LVDS Receiver DC Specifications

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

-

2.0

-

VCC

V

VIL

Low Level Input Voltage

-

GND

-

0.8

V

VOH

High Level Output Voltage

IOH=-4mA (Data)

IOH=-8mA (Clock)

2.4

-

V

VOL

Low Level Output Voltage

IOL=4mA (Data)

IOL=8mA (Clock)

-

0.4

V

IIN

Input Current

GND  VIN  VCC

-

10

A

Table 7. LVCMOS DC Specifications

LVCMOS Output Load Limitation

The output load is limited so that the junction temperature does not exceed 125C.

0.0

5.0

10.0

15.0

20.0

25.0

8 28 48 68 88 108

CLKOUT [MHz]

Output Load [pF]

Ta=70℃

Ta=85℃

Figure 6. LVCMOS Output Load Limitation

THC63LVDR84C_Rev.1.20_E

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Switching Characteristics

Over recommended operating supply and temperature range unless otherwise specified

Symbol

Parameter

Min

Typ*

Max

Unit

tRCP

RCLK and CLKOUT Transition Time

8.92

T

125

ns

tRCH

LVCMOS CLKOUT High Time

-

T/2

-

ns

tRCL

LVCMOS CLKOUT Low Time

-

T/2

-

ns

tRCD

RCLK IN to CLKOUT Delay

-

(3/14+3)×T

-

ns

tRS

LVCMOS Data Setup to CLKOUT

0.35×T - 0.3

-

ns

tRH

LVCMOS Data Hold from CLKOUT

0.45×T - 1.6

-

ns

tTLH

LVCMOS Low to High Transition Time

-

0.7

1.0

ns

tTHL

LVCMOS High to Low Transition Time

-

0.7

1.0

ns

tSK

LVDS Receiver Skew Margin

PCLK=65MHz

-0.55

-

0.55

ns

PCLK=112MHz

-0.25

-

0.25

tRIP1

LVDS Input Data Position0

- tSK

0.0

+ tSK

ns

tRIP0

LVDS Input Data Position1

T/7- tSK

T/7

T/7+ tSK

ns

tRIP6

LVDS Input Data Position2

2T/7- tSK

2T/7

2T/7+ tSK

ns

tRIP5

LVDS Input Data Position3

3T/7- tSK

3T/7

3T/7+ tSK

ns

tRIP4

LVDS Input Data Position4

4T/7- tSK

4T/7

4T/7+ tSK

ns

tRIP3

LVDS Input Data Position5

5T/7- tSK

5T/7

5T/7+ tSK

ns

tRIP2

LVDS Input Data Position6

6T/7- tSK

6T/7

6T/7+ tSK

ns

tRPLL

Phase Lock Loop Set

-

10.0

ms

*Typ values are at the conditions of VCC33=3.3V and Ta = +25ºC

Table 8. LVCMOS & LVDS Receiver AC Specifications

THC63LVDR84C_Rev.1.20_E

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AC Timing Diagrams

LVDS Input

RCLK+

RA+/- RA6 RA5 RA4 RA3 RA2 RA1 RA0

RB6 RB5 RB4 RB3 RB2 RB1 RB0

RC6 RC5 RC4 RC3 RC2 RC1 RC0

RD6 RD5 RD4 RD3 RD2 RD1 RD0

tRIP6

tRIP5

tRIP4

tRIP3

tRIP2

tRIP1

tRIP0

(Differential)

RB+/-

RC+/-

RD+/-

Next Cycle

Vdiff = 0V　Vdiff = 0V　

tRCP

Current CyclePrevious Cycle

Note:Vdiff=(RCLK+)-(RCLK-)

Figure 7. LVDS Input Data Position

LVCMOS Output

tTLH

80％

20％

80％

20％

tTHL

CL=8pF

Figure 8. LVCMOS Output Load and Transition Time

CLKOUT

tRCP

tRCH tRCL

VCC/2 VCC/2

VCC/2

tRS tRH

RA0-RA6

RB0-RB6

RC0-RC6

RD0-RD6

VCC/2

VCC/2 Valid Data

Figure 9. LVCMOS Output Setup and Hold Time

THC63LVDR84C_Rev.1.20_E

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Input to Output Delay

RCLK+ Vdiff = 0V

VCC/2

tRCD

CLKOUT

Note:Vdiff=(RCLK+)-(RCLK-)

Figure 10.Input Clock to Output Clock Delay Time

Phase Lock Loop Set Time

VCC33 3.0V

RCLK+/-

/PDWN VCC/2

CLKOUT VCC/2

tRPLL

Figure 11. PLL Lock Loop Set Time

THC63LVDR84C_Rev.1.20_E

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Application note

Display Data Mapping Example

Transmitter

VESA format

JEIDA format

Receiver

6bit(18bpp)

8bit(24bpp)

6bit(18bpp)

8bit(24bpp)

TA0

R0

R2

RA0

TA1

R1

R3

RA1

TA2

R2

R4

RA2

TA3

R3

R5

RA3

TA4

R4

R6

RA4

TA5

R5

R7

RA5

TA6

G0

G2

RA6

TB0

G1

G3

RB0

TB1

G2

G4

RB1

TB2

G3

G5

RB2

TB3

G4

G6

RB3

TB4

G5

G7

RB4

TB5

B0

B2

RB5

TB6

B1

B3

RB6

TC0

B2

B4

RC0

TC1

B3

B5

RC1

TC2

B4

B6

RC2

TC3

B5

B7

RC3

TC4

Hsync

RC4

TC5

Vsync

RC5

TC6

DE

RC6

TD0

-

R6

-

R0

RD0

TD1

-

R7

-

R1

RD1

TD2

-

G6

-

G0

RD2

TD3

-

G7

-

G1

RD3

TD4

-

B6

-

B0

RD4

TD5

-

B7

-

B1

RD5

TD6

-

N/A

-

N/A

RD6

Note : Use TA to TC channels and open TD channel for 6bit application.

Table 9. Data Mapping for VESA & JEIDA RGB Color format

THC63LVDR84C_Rev.1.20_E

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System Connection Example

CLKIN

R2

R3

R4

R5

R6

R7

G2

G3

G4

G5

G6

G7

B2

B3

B4

B5

B6

B7

HSYNC

VSYNC

DE

R0

R1

G0

G1

B0

B1

CLKIN

TA0

TA1

TA2

TA3

TA4

TA5

TA6

TB0

TB1

TB2

TB3

TB4

TB5

TB6

TC0

TC1

TC2

TC3

TC4

TC5

TC6

TD0

TD1

TD2

TD3

TD4

TD5

TD6

/PDWN/PDWN

RS

VCC33

R/F

GND

VCC

VCC33

LVDS GND

RA-

RA+

RB-

RB+

LVDS VCC

RC-

RC+

RCLK-

RCLK+

RD-

RD+

PLL GND

PLL VCC

TA-

TA+

TB-

TB+

TC-

TC+

TCLK-

TCLK+

TD-

TD+

Ferrite Bead

0.1uF 0.01uF

THC63LVDM83D

PCB(Transmitter)

0.1uF

0.1uF0.01uF

CLKOUT

RA0

RA1

RA2

RA3

RA4

RA5

RA6

RB0

RB1

RB2

RB3

RB4

RB5

RB6

RC0

RC1

RC2

RC3

RC4

RC5

RC6

RD0

RD1

RD2

RD3

RD4

RD5

RD6

LVDS GND

PLL GND

PLL VCC

0.1uF 0.01uF

LVDS VCC

0.1uF 0.01uF

/PDWN/PDWN

CLKOUT

R2

R3

R4

R5

R6

R7

G2

G3

G4

G5

G6

G7

B2

B3

B4

B5

B6

B7

HSYNC

VSYNC

DE

R0

R1

G0

G1

B0

B1

OPEN

THC63LVDF(R)84C

GND

VCC

VCC33

Ferrite Bead

0.1uF0.01uF

PCB(Receiver)

100ohm

GND GND

0.01uF

100ohm pair Cable

or

PCB trace

Figure 12. Connection Example with JEIDA Format

THC63LVDR84C_Rev.1.20_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 LVDS-Tx and THC63LVDR84C 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.

THC63LVDR84C

LVDS-Tx THC63LVDR84C

RCLK+

RCLK-

Figure 13. Multi Drop Connection

4) Asynchronous use

Asynchronous using such as following systems is not recommended.

THC63LVDR84C

THC63LVDR84CLVDS-Tx

LVDS-Tx

IC

CLKOUT

DATA

IC

RCLK+

RCLK-

RCLK+

RCLK-

CLKOUT

DATA

THC63LVDR84C

IC

RCLK+

RCLK-

RCLK+

RCLK-

CLKOUT

DATA

IC

Figure 14. Asynchronous Use

THC63LVDR84C_Rev.1.20_E

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Package

Figure 15. Package Diagram

THC63LVDR84C_Rev.1.20_E

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Reference Land Pattern

Figure 16. 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.

THC63LVDR84C_Rev.1.20_E

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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