51 Pin Lvds | Pinout Datasheet Work
Look for a string like: G150XG01 V3 , NL10276BC20-18D , or AA121TH01 .
Manufacturers that offer custom LVDS assemblies will work directly from your pinout tables or schematic diagrams to build a cable that matches your exact requirements. This is far more reliable than attempting to reverse-engineer a cable from a photograph.
Pulling this pin to Ground (GND) or leaving it low usually configures the controller for the VESA format.
Modern 51-pin panels often integrate capacitive touch.
Have a specific 51-pin display you're working with? Share the model number in the comments, or consult a hardware engineer for final schematic review. 51 pin lvds pinout datasheet
Always measure the power rail orientation before connecting an LVDS cable. While pins 44–48 are standard for VCC on many 51-pin fixtures, some legacy or proprietary panels flip the configuration entirely, putting VCC on pins 1–5. Reversing this will instantly destroy the T-CON board processing chip. 2. Identifying Cable Degradation
The signals on a 51-pin connector are categorized into four primary groups:
Before plugging in the cable, check the resistance between the VCC pins and GND pins. A reading close to zero ohms indicates a short circuit on the panel side.
While specific pinouts can vary by manufacturer (e.g., Samsung vs. LG), most 51-pin interfaces follow a similar logic for power, ground, and differential signal pairs. Pin Number Signal Type Description VCC / Power Power supply (typically 12V for large panels) GND Ground Distributed throughout to reduce EMI Even Channels LVDS Signals Look for a string like: G150XG01 V3 ,
While specific manufacturers like or LG may have slight variations, a typical 51-pin datasheet for a 4K panel generally follows this functional grouping: DS90LV047A 3-V LVDS Quad CMOS Differential Line Driver
The 51 pins are not random; they are organized into functional groups. A standard 51-pin LVDS interface (based on the standard) typically includes:
is predominantly found in high-resolution displays (like Full HD and 4K TV screens) or dual-channel, 8-bit, and 10-bit color depth environments.
While you must always cross-reference the exact datasheet for your specific panel model, many modern Full HD panels follow a standardized configuration. Below is a common pinout layout for a dual-channel 8-bit/10-bit FI-RE51S interface: Pin Number Signal Name Description Panel Power Supply (+5V / +12V) 5 - 8 Ground Connection 9 Odd_O3N / JEIDA_Sel Odd Channel Data 3 Negative (or Bit Depth Selector) 10 Odd Channel Data 3 Positive 11 Odd Channel Clock Negative 12 Odd Channel Clock Positive 13 Odd Channel Data 2 Negative 14 Odd Channel Data 2 Positive 15 Odd Channel Data 1 Negative 16 Odd Channel Data 1 Positive 17 Odd Channel Data 0 Negative 18 Odd Channel Data 0 Positive 19 - 22 Ground Shielding 23 Even Channel Data 3 Negative 24 Even Channel Data 3 Positive 25 Even_CLKIN Even Channel Clock Negative 26 Even_CLKIP Even Channel Clock Positive 27 Even Channel Data 2 Negative 28 Even Channel Data 2 Positive 29 Even Channel Data 1 Negative 30 Even Channel Data 1 Positive 31 Even Channel Data 0 Negative 32 Even Channel Data 0 Positive 33 - 36 37 Odd Channel Data 4 Negative (For 10-bit panels) 38 Odd Channel Data 4 Positive (For 10-bit panels) 39 Even Channel Data 4 Negative (For 10-bit panels) 40 Even Channel Data 4 Positive (For 10-bit panels) 41 - 45 NC / Options No Connection or Vendor Specific Controls 46 - 51 BL_EN / PWM / VLED Backlight Enable, Dimming Control, and Backlight Power Critical Datasheet Variables to Watch For Pulling this pin to Ground (GND) or leaving
The 51-pin interface standard features a :
The 51-pin LVDS (Low-Voltage Differential Signaling) interface is a high-speed serial standard commonly used in Full HD (1080p)
FIR-E51PIN LVDS Cable 2 Ch 8-bit 51 Pins 51pin Dual ... - AliExpress
LVDS is a low-power, low-voltage differential signaling standard that uses a differential signal to transmit data. It consists of two wires, one for the positive signal (TX+) and one for the negative signal (TX-). The receiver detects the difference between the two signals, allowing for high-speed data transmission with low electromagnetic interference (EMI).