Please refer to the English Version as our Official Version.

Europe: France~~(Français)~~ Germany~~(Deutsch)~~ Italy~~(Italia)~~ Russian~~(русский)~~ Poland~~(polski)~~ Czech~~(Čeština)~~ Luxembourg~~(Lëtzebuergesch)~~ Netherlands~~(Nederland)~~ Iceland~~(íslenska)~~ Hungarian~~(Magyarország)~~ Spain~~(español)~~ Portugal~~(Português)~~ Turkey~~(Türk dili)~~ Bulgaria~~(Български език)~~ Ukraine~~(Україна)~~ Greece~~(Ελλάδα)~~ Israel~~(עִבְרִית)~~ Sweden~~(Svenska)~~ Finland~~(Svenska)~~ Finland~~(Suomi)~~ Romania~~(românesc)~~ Moldova~~(românesc)~~ Slovakia~~(Slovenská)~~ Denmark~~(Dansk)~~ Slovenia~~(Slovenija)~~ Slovenia~~(Hrvatska)~~ Croatia~~(Hrvatska)~~ Serbia~~(Hrvatska)~~ Montenegro~~(Hrvatska)~~ Bosnia and Herzegovina~~(Hrvatska)~~ Lithuania~~(lietuvių)~~ Spain~~(Português)~~ Switzerland~~(Deutsch)~~ United Kingdom~~(English)~~

Asia/Pacific: Japan~~(日本語)~~ Korea~~(한국의)~~ Thailand~~(ภาษาไทย)~~ Malaysia~~(Melayu)~~ Singapore~~(Melayu)~~ Vietnam~~(Tiếng Việt)~~ Philippines~~(Pilipino)~~

Africa, India and Middle East: United Arab Emirates~~(العربية)~~ Iran~~(فارسی)~~ Tajikistan~~(فارسی)~~ India~~(हिंदी)~~ Madagascar~~(malaɡasʲ)~~

South America / Oceania: New Zealand~~(Maori)~~ Brazil~~(Português)~~ Angola~~(Português)~~ Mozambique~~(Português)~~

North America: United States~~(English)~~ Canada~~(English)~~ Haiti~~(Ayiti)~~ Mexico~~(español)~~

Home Products Integrated Circuits (ICs)Specialized ICs~~DS90C387VJD/NOPB~~

Image may be representation.
See specifications for product details.

~~Favorite~~

EXPRESS OPTION

Payment method

DS90C387VJD/NOPB - Texas Instruments

Name: Texas Instruments DS90C387VJD/NOPB
Brand: Texas Instruments
SKU: DS90C387VJD/NOPB
Price: 4.327 USD
Availability: InStock
Rating: 5 (10 reviews)

Manufacturer Part Number: DS90C387VJD/NOPB

Manufacturer: Texas Instruments

Allelco Part Number: 41D-DS90C387VJD/NOPB

Warranty: 1 Year Allelco Warranty - Find out more

Stock Status:: 4,540 pcs available, New & Original

Parts Description: TQFP-100(14x14)

Data sheet: -

Category: Integrated Circuits (ICs) > Specialized ICs

RoHs Status

~~Compare~~

Our certification

In stock: 4540

Unit Price: $11.801
Subtotal: $0.00

Want a better price?
Add to Cart and Submit RFQ now, we'll contact you immediately.

Quantity	Unit Price	Ext. Price
1+	$11.801	$11.80
200+	$4.567	$913.40
500+	$4.406	$2,203.00
1000+	$4.327	$4,327.00

The above prices does not include taxes and freight rates, which will be calculated on the order pages.

Specifications

DS90C387VJD/NOPB Tech Specifications
Texas Instruments - DS90C387VJD/NOPB technical specifications, attributes, parameters and parts with similar specifications to Texas Instruments - DS90C387VJD/NOPB

Product Attribute	Attribute Value
Part Number	DS90C387VJD/NOPB
Package	TQFP-100(14x14)
Description	TQFP-100(14x14)
Stock Condition	Get 4540 pcs available quantity at Allelco
Payment	PayPal / TT / Credit Card / Western Union
Allelco Certifications	ESD / ISO 9001 / ISO 13485 / ISO 28000

Product Attribute	Attribute Value
Manufacturer	Texas Instruments
RoHs Status	-
Warranty	100% Perfect Functions
Transport port	Hong Kong
Shipping by	DHL / FedEx / UPS / TNT / SF Express
RFQ Email	info@allelco.com

Parts Introduction

Manufacturer Part Number

DS90C387VJD/NOPB

Manufacturer

Texas Instruments

Introduction

The DS90C387VJD/NOPB is a high-performance LVDS (Low Voltage Differential Signaling) driver that supports the FPD-Link protocol. It is designed to provide a reliable and efficient data transmission solution for a variety of applications, including display interfaces, video processing, and high-speed data communication.

Product Features and Performance

Supports data rates up to 4.76 Gbps

8 driver channels and 0 receiver channels

Operates on a supply voltage of 3V to 3.6V

Supports a wide operating temperature range of -10°C to 70°C

Surface mount package with a 100-TQFP (14x14) form factor

Low power consumption and high power efficiency

Product Advantages

Reliable and high-speed data transmission

Efficient power management

Versatile compatibility and wide operating temperature range

Compact and space-saving design

Key Reasons to Choose This Product

Robust performance and stability for critical applications

Cost-effective solution with superior power efficiency

Seamless integration and compatibility with a wide range of systems

Trusted Texas Instruments brand and quality assurance

Quality and Safety Features

Rigorous quality control and testing processes

Compliance with industry standards and regulations

Robust design for enhanced reliability and durability

Compatibility

Compatible with various display interfaces, video processing systems, and high-speed data communication applications

Application Areas

Display interfaces

Video processing

High-speed data communication

Industrial automation

Medical equipment

Telecommunications infrastructure

Product Lifecycle

The DS90C387VJD/NOPB is an active product in our website's sales team's portfolio. There are no immediate plans for discontinuation, and it remains a viable option for customers. However, as technology evolves, there may be newer or more advanced models available in the future. Customers are advised to contact our website's sales team for the latest product information and availability.

Frequently Asked Questions(FAQ)

What are the key electrical specifications of the DS90C387VJD/NOPB that influence high-speed signal integrity in FPD-Link applications, and how do they compare to typical LVDS driver requirements?: The DS90C387VJD/NOPB operates with a supply voltage range of 3V to 3.6V, which aligns closely with standard low-voltage differential signaling (LVDS) interface standards used in high-speed serial communication. Its data rate capability reaches up to 4.76 Gbps per channel, making it suitable for driving high-resolution displays and multi-channel sensor data streams over point-to-point links. This exceeds many conventional LVDS drivers that typically cap at 1 Gbps or lower, enabling support for advanced display technologies such as 4K video transmission. When evaluating signal integrity, designers must consider this bandwidth in conjunction with the device’s internal termination and skew management features, which help maintain timing alignment across eight parallel channels—critical for minimizing intersymbol interference in long trace environments.

How does the operating temperature range of the DS90C387VJD/NOPB impact its deployment in industrial versus consumer-grade systems, and what design considerations arise from this limitation?: With an operating temperature specification of -10°C to +70°C, the DS90C387VJD/NOPB is optimized for commercial-grade applications rather than extended industrial environments. While sufficient for most embedded computing and display control systems within office or retail settings, this range may be inadequate for outdoor kiosks, automotive infotainment modules exposed to engine bay heat, or medical equipment requiring broader thermal tolerance. Engineers selecting this component should verify ambient conditions during worst-case power-up sequences and ensure adequate PCB thermal relief. In contrast to automotive-grade alternatives rated to –40°C to +125°C, this part trades ruggedness for cost efficiency—a common trade-off when targeting non-extreme use cases where FPD-Link’s compact footprint justifies the narrower thermal envelope.

Can the DS90C387VJD/NOPB be used in bidirectional communication scenarios, and if not, what architectural modifications would enable full-duplex data transfer using this component?: The DS90C387VJD/NOPB is unidirectional only—it contains eight transmitter channels but no receiver circuitry, classifying it strictly as a transmitter (driver-only). Therefore, it cannot participate in bidirectional or half-duplex communication on its own. To implement full-duplex data flow, system architects must pair this device with a complementary receiver IC such as the DS90CR287 or another FPD-Link-compatible receiver capable of accepting the LVDS-encoded signals. Additionally, since the transmitter lacks built-in loopback or echo cancellation, separate receive path isolation must be designed to prevent signal reflection or crosstalk between transmit and return paths. This separation often requires careful routing of differential pairs and consideration of cable shielding in multi-drop configurations.

In terms of pinout and package compatibility, how does the 100-TQFP (14x14) form factor of the DS90C387VJD/NOPB affect board layout decisions compared to smaller QFN or SOIC packages?: The DS90C387VJD/NOPB uses a 100-pin TQFP package measuring 14×14 mm, offering ample I/O density for an eight-channel driver without resorting to ball-grid array formats. This facilitates easier soldering inspection and rework compared to BGA variants, though it occupies more board real estate than compact QFNs. From a layout perspective, the square outline allows symmetric placement around clock and power planes, aiding impedance matching for all eight differential outputs. However, the larger size increases parasitic capacitance and inductance on adjacent traces, necessitating tighter spacing rules for high-speed lines. Designers should allocate generous keep-out zones around the package to minimize coupling with sensitive analog sections and avoid routing other signals beneath the component due to potential ground plane discontinuities.

What role does the FPD-Link protocol play in the functionality of the DS90C387VJD/NOPB, and how does it differ from raw LVDS signaling in practical system integration?: The DS90C387VJD/NOPB implements the FPD-Link protocol, which is a standardized extension of LVDS specifically engineered for flat-panel display interfaces. Unlike raw LVDS, FPD-Link includes embedded clock recovery, deterministic latency, and error-resistant encoding tailored for video data transmission over point-to-point links. This protocol enables reliable delivery of pixel clocks, synchronization signals, and control commands alongside RGB or YCbCr video payloads. When integrating the DS90C387VJD/NOPB into a system, engineers must ensure downstream components also support FPD-Link decoding, as generic LVDS receivers will fail to interpret the packetized structure correctly. The benefit lies in simplified PCB routing and reduced EMI, as FPD-Link minimizes DC content through AC-coupled signaling and balanced transitions.

Given its maximum data rate of 4.76 Gbps per lane, what are the practical limitations on trace length and material selection when implementing a design using the DS90C387VJD/NOPB?: At 4.76 Gbps, each differential pair transmitted by the DS90C387VJD/NOPB approaches the Nyquist frequency limit for reliable transmission, introducing significant challenges related to attenuation, dispersion, and jitter accumulation. Over FR-4 PCBs, usable trace lengths rarely exceed 10–15 cm without equalization or pre-emphasis, depending on layer stackup and via stubs. To mitigate losses, designers should use controlled-impedance microstrip or stripline routing with characteristic impedance maintained near 100 Ω. High-loss materials like standard FR-4 can cause unacceptable bit errors beyond short distances; thus, embedding low-loss prepreg (e.g., Megtron6 or Isola IS430) becomes necessary for longer runs. Additionally, insertion loss budgets must account for connectors, vias, and cable attenuation if interfacing with external cables, potentially requiring active compensation at the receiver end.

How does the absence of internal termination in the DS90C387VJD/NOPB affect impedance matching strategies in end-of-line designs, and what resistor values are commonly implemented?: The DS90C387VJD/NOPB does not integrate internal differential termination resistors, requiring external 100 Ω ±1% resistors placed directly at the receiving IC’s input pins. These resistors match the characteristic impedance of the transmission line and prevent reflections caused by impedance mismatches. Placement proximity to the receiver is critical—ideally within 5 mm—to avoid creating stubs that distort signal edges. Some reference designs place these resistors slightly closer to the transmitter, but best practice favors receiver-side termination to protect against ESD events. Omitting internal termination reduces die area and power consumption but shifts responsibility for precision matching to PCB layout and BOM cost, increasing assembly complexity relative to integrated-termination alternatives.

When comparing the DS90C387VJD/NOPB to alternative FPD-Link transmitter devices, what advantages does its eight-channel configuration offer in multi-sensor fusion systems?: The DS90C387VJD/NOPB supports eight independent LVDS output lanes, allowing simultaneous transmission from multiple cameras, ADCs, or digital sensors over a single serialized link. This contrasts with single-lane or four-lane alternatives, reducing connector count and simplifying cabling in applications like machine vision, robotics, or automotive surround-view systems. By multiplexing eight data sources onto one physical interface, designers achieve higher aggregate throughput while maintaining backward compatibility with existing FPD-Link infrastructure. However, this requires careful arbitration logic upstream to serialize inputs efficiently, and latency becomes a concern if not managed properly. The eight-channel architecture thus enables compact, scalable sensor aggregation but demands robust firmware coordination to avoid data collisions or dropped frames.

Customers Also Interested in

Recommended Products

Customer Reviews

Evaluation: 10 Articles

Dani***alkerTech

Jun 1, 2026

Product works, but setup took more effort than expected. Once configured the MCU ran reliably, although documentation support felt older compared with newer platforms. Fine for maintenance projects.
Yuki***aka88

May 26, 2026

信号通信プロジェクトでこのRS-485トランシーバーを使用しました。設置は簡単で、長距離ケーブルでも通信は安定していました。消費電力も、以前使用していたものより低くなっています。
Stev***aker

May 20, 2026

Solid diode for power rectification. Works well in switching circuits.
Bran***Lewis

May 11, 2026

Compact FPGA with good performance. Suitable for basic signal processing tasks.
Oliv***arris

May 7, 2026

Reliable I/O expander. Works well in embedded control applications.
Jess***Jones

Apr 17, 2026

It offers good value for the price, and the specifications match the description. I’ve been using it for two days with no issues, and I’ll definitely buy it again if I need it in the future.
Mich***Smith

Apr 17, 2026

Shipping was on time, the component pins are neatly aligned, and I tested 10 of them with a multimeter—all readings were within the specified range. Highly recommended.
Aman***arris

Apr 3, 2026

It was great—the entire process, from placing the order to receiving the package, went very smoothly. The components were consistent, the price was fair, and I had a very pleasant shopping experience.
Mike***nch

Apr 3, 2026

Better than expected! The resistance and capacitance readings were spot-on, and it passed the test on the first try. The service was reliable, and the packaging was thoughtful—I highly recommend it.
Daic***K.

Mar 23, 2026

Very good. No issue after long time testing.

Write a Review

Your Email address will not be published.

Shipment

Delivery Time

In-stock items can be shipped within 24 hours. Some parts will be arranged for delivery within 1-2 days from the date all items arrive at our warehouse. And Allelco ships order once a day at about 17:00, except Sunday. Once the goods are shipped, the estimated delivery time depends on the shipping methods and Delivery destination. The table below shows are the logistic time for some common countries.

Delivery Cost

Use your express account for shipment if you have one.
Use our account for the shipment. Refer to the table below for the approximate charges.

(Different time frame / countries / package size has different price.)

Delivery Method

Global Common Shipment by DHL / UPS / FedEx / TNT / EMS / SF we support.
Others more shipping ways, please get in touch with your customer manager.

Common Countries Logistic Time Reference
Region	Country	Logistic Time(Day)
America	United States	5
America	Brazil	7
Europe	Germany	5
	United Kingdom	4
	Italy	5
Oceania	Australia	6
Oceania	New Zealand	5
Asia	India	4
Asia	Japan	4
Middle East	Israel	6

DHL & FedEx Shipment Charges Reference
Shipment charges(KG)	Reference DHL(USD$)
0.00kg-1.00kg	USD$30.00 - USD$60.00
1.00kg-2.00kg	USD$40.00 - USD$80.00
2.00kg-3.00kg	USD$50.00 - USD$100.00

Note:: The above table is for reference only. There may have some data bias for the uncontrollable factors.
Contact us if you have any questions.

QC (Quality Warranty)
Payment Support
Packaging
Certifications & Memberships

QC (Quality Warranty)

Allelco is committed to exceeding customer expectations through customer service excellence, order accuracy, and on-time delivery.
This is achieved through our commitment to the continual improvement of our processes, services, and products.

Strict quality inspection builds a solid foundation for electronic component quality.

Visual inspection
Performance testing and reliability verification
Standardized full-process testing
Precise control of every parameter

We eliminate defective components and ensure the stable operation of electronic devices through professional quality standards.

Quality Inspection

Payment Support

The payment method can be chosen from the methods shown below: Wire Transfer (T/T, Bank Transfer), Western Union, Credit card, PayPal.

Stable Delivery, Sincere Partnership — Your Faithful Supply Chain Partner

Efficient Supply Management
Cost-Saving Procurement
Fast Sourcing & Delivery

Contact us if you have any questions.

Phone: +00852 9146 4856
Email: info@allelco.com

Packaging

Electrostatic Discharge Protection and Handling

All electrostatic-sensitive components are handled in accordance with electrostatic discharge control procedures. The products are hermetically sealed in anti-static safe packaging to prevent electrostatic damage. Appropriate labeling is also applied for identification and traceability. This ensures product integrity during storage, handling and transportation.

ESD

Certifications & Memberships

Third-party certified, strict quality control. Our certification

ISO 9001: 2015
ISO 13485: 2016
ISO 14001: 2015
ISO 28000: 2007
ISO 45001: 2018
GB/T 27922-2011

SMTA
IPC
ESD
PSMA