Optoelectronic Hybird Integration | E-mail:sales1@cqwiseworld.com
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As a leading manufacturer and supplier of advanced optical components, we present the Dual-channel Thin-film LiNbO3 Intensity Modulator Module. Engineered specifically for high-volume integration, this device completely redefines high-speed transmission standards for demanding industry applications.
Core Material: Premium Thin-film Lithium Niobate (LiNbO3)
Performance: Up to 50GHz bandwidth with sub-3V Vpi
Form Factor: Ultra-compact 30mm x 20mm x 10mm hermetically sealed housing
Target Application: High-speed optical communication and microwave optical links
Step into the future of optical signal processing with our Dual-channel Thin-film LiNbO3 Intensity Modulator Module. Crafted with meticulous precision, the cool, metallic exterior of its hermetically sealed casing houses a revolutionary thin-film lithium niobate architecture. When integrated into your communication infrastructure, it silently and efficiently translates electrical signals into flawless optical streams. Unlike bulky traditional crystal modulators that consume excessive space and power, this refined module feels incredibly lightweight in the hand yet delivers heavyweight performance. By drastically reducing the half-wave voltage to under 3V, it minimizes thermal output and power consumption, allowing your system to run cooler and more efficiently. The sheer compactness of the 30mm by 20mm by 10mm footprint liberates critical board space, empowering engineers to design denser, more capable arrays without compromising on signal integrity. Every edge and coupling point is machined to exacting tolerances, ensuring a seamless, snap-in fit that instantly elevates the transmission capabilities of your high-speed networks, microwave links, and precision delay lines.
To assist engineering teams and procurement specialists in evaluating system compatibility, the following table details the precise technical parameters of our intensity modulator module. These specifications reflect our strict commitment to delivering consistent, high-grade optical performance for demanding volume applications.
| Parameter | Specification |
|---|---|
| Product Name | Dual-channel Thin-film LiNbO3 Intensity Modulator Module |
| Modulator Type | Intensity Modulator |
| Material | Thin-film LiNbO3 (Lithium Niobate) |
| Channel Configuration | Dual-channel |
| Frequency Bandwidth | Up to 50GHz |
| Half-wave Voltage (Vpi) | < 3V |
| Insertion Loss | < 5dB |
| Operating Temperature | -40°C to 70°C |
| Packaging Technology | Hermetically packaging / High-precision coupling process |
| Dimensions | 30mm * 20mm * 10mm |
| Key Advantages | Wide frequency band, low Vpi, small size, light weight, small bending radius of optical fiber |
These verified parameters ensure that every unit rolling off our manufacturing line meets the stringent requirements of advanced telecommunications and aerospace integrators, providing a reliable foundation for your next-generation optical architectures.
Our engineering focus centers on solving the most pressing bottlenecks in modern optical networking. By transitioning to advanced material platforms, we have unlocked a suite of operational benefits that directly impact your bottom line and system efficacy.
Operating at frequencies up to 50GHz, this module effortlessly handles massive data torrents. It eliminates network congestion and future-proofs your infrastructure against escalating bandwidth demands, ensuring your systems remain relevant for years to come.
With a half-wave voltage (Vpi) strictly maintained below 3V, the device drastically reduces the electrical burden on your driving circuits. This cuts down overall power consumption and significantly lowers thermal management costs across your server racks.
An insertion loss of less than 5dB ensures that your signal retains its brilliance and strength across the transmission line. This efficiency minimizes the need for costly downstream amplification, preserving the integrity of your optical budget.
Designed to accommodate a remarkably small bending radius, the integrated optical fibers allow for tight, stress-free routing within crowded enclosures. This prevents micro-bending losses and physical fiber degradation, ensuring long-term physical reliability.
For communication equipment developers and scientific research institutions, raw transmission speed and minimal signal degradation are absolutely non-negotiable. This module is meticulously engineered to push the boundaries of electro-optic conversion, ensuring your infrastructure operates at peak efficiency.
The expansive frequency response reaching up to 50GHz guarantees that complex, high-baud-rate modulation formats are executed with pristine clarity. This massive bandwidth capacity effortlessly handles immense data torrents, eliminating network congestion and future-proofing your architecture.
By dramatically lowering the half-wave drive voltage (Vpi) to strictly under 3V, we enable seamless compatibility with low-power CMOS drivers. This critical synergy reduces the overall energy footprint of your hardware racks, minimizing thermal output and cutting down on expensive cooling requirements.
Maintaining an insertion loss of less than 5dB preserves the vital optical budget of your entire network. This high-transmission efficiency translates directly to longer reach and fewer repeater stations in long-haul links, significantly lowering deployment costs.
Moving away from legacy bulk crystals, our adoption of cutting-edge materials and enclosure techniques ensures that your systems remain resilient, compact, and highly responsive under rigorous operational conditions.
Utilizing thin-film lithium niobate transforms the electro-optic landscape. This material confines the optical mode more tightly, resulting in stronger electro-optic interaction and dramatically enhanced modulation efficiency compared to traditional substrates.
Every module undergoes a meticulous, high-precision coupling process. This craftsmanship ensures flawless alignment between the chip and the fiber, maximizing light transfer and reducing back-reflection to near-zero levels for an impeccably clean signal.
The delicate internal photonics are shielded within a hermetically sealed package. This robust barrier completely blocks moisture, dust, and atmospheric contaminants, ensuring decades of reliable operation without performance drift even in challenging environments.
Space is a premium commodity in aerospace, drone payloads, and high-density data centers. We have meticulously engineered this module to deliver maximum performance within an incredibly constrained physical envelope.
Measuring a mere 30mm by 20mm by 10mm, this module occupies a fraction of the volume required by legacy modulators. It allows designers to pack more channels into standard rack units or tight avionic bays, maximizing spatial efficiency.
The significant reduction in mass not only lowers shipping and handling costs for volume suppliers but also provides a crucial advantage in airborne and space-bound applications where every single gram dictates fuel efficiency and payload capacity.
The sleek, block-like geometry and strategic port placements make it an ideal candidate for optoelectronic hybrid integration. It allows multiple units to be stacked or arrayed with minimal clearance requirements, streamlining complex system assemblies.
Industrial and military-grade applications demand components that refuse to compromise, regardless of the external conditions. This module is built to thrive where standard commercial optics typically fail.
Capable of flawless operation from a freezing -40°C up to a scorching 70°C, the device maintains stable phase and intensity modulation without requiring bulky, power-hungry active thermal control systems.
The combination of a solid thin-film substrate and rigid hermetic packaging means the internal optical paths remain perfectly aligned. It easily withstands the harsh mechanical vibrations of industrial machinery or launch vehicles.
By isolating the active components from environmental stressors, the module guarantees a highly stable output over its entire lifecycle. This drastically reduces maintenance intervals and lowers the total cost of ownership for system operators.
Ease of integration accelerates time-to-market. We have designed this modulator to seamlessly handshake with your existing infrastructure, ensuring a frictionless upgrade path for your engineering teams.
The module interfaces smoothly with industry-standard optical fibers, ensuring precise polarization alignment and minimal splice losses. This flexibility allows it to adapt to your specific cabling requirements without additional adapters.
Equipped with high-grade optical terminations and robust RF interfaces, it guarantees secure, low-reflection physical connections right out of the box. This attention to interface quality prevents signal degradation at the connection points.
The predictable electrical impedance and standardized physical footprint mean that integrators can drop this module directly into existing microwave photonic links or automated test equipment without requiring extensive system redesigns.
In the realm of analog optical transmission and high-frequency digital networks, signal purity is paramount. The dual-channel architecture of this device provides unparalleled control over the light wave.
The dual-channel configuration enables precise differential signaling. This naturally suppresses common-mode noise, delivering a remarkably clean and stable signal that is vital for sensitive microwave photonic applications.
By maintaining strict control over the phase-to-intensity relationship, the modulator exhibits exceptionally low chirp. This prevents pulse broadening over long distances, ensuring the data arrives exactly as it was originally sent.
The precision etching of the thin-film waveguides ensures deep modulation depths and a high extinction ratio. This provides a crisp, unambiguous distinction between signal states, allowing for error-free digital decoding at the receiver end.
By aligning cutting-edge material science with practical engineering requirements, this modulator serves as the critical engine for a wide array of advanced technological sectors.
Perfectly suited for converting high-frequency analog RF signals into the optical domain. It enables low-loss, interference-free transmission over vast distances, which is essential for modern radar and antenna remoting systems.
Acts as the core modulation unit in next-generation telecom networks. It effortlessly handles the rigorous demands of 50GHz+ coherent transmission and ultra-dense wavelength-division multiplexing architectures.
The stable phase characteristics and low insertion loss make it an ideal component for precise optical signal buffering. It provides the exact timing control required in advanced phased-array radar systems.
Delivers the high linearity and low noise floor required for transporting sensitive analog data. It ensures absolute fidelity in scientific instrumentation, aerospace sensing networks, and specialized industrial monitoring.
Partnering with a dedicated manufacturer of optoelectronic solutions means securing a competitive edge in your supply chain. We are committed to empowering your projects with uncompromising quality and reliable volume delivery.
By controlling the entire fabrication process from wafer processing to final hermetic sealing, we eliminate middlemen. This ensures you receive premium components at highly competitive procurement rates.
Every single module is subjected to rigorous environmental and RF testing before it leaves our facility. We guarantee that the specifications on paper perfectly match the performance in your laboratory.
Whether you require a handful of units for prototyping or thousands for global deployment, our agile manufacturing lines are equipped to meet your delivery schedules without ever compromising on precision.
Our team of optoelectronic specialists is always on standby to assist with integration challenges. We offer deep technical insights to help you maximize the performance of our modulators in your specific system architecture.
