MTP Jumpers

MTP® jumpers enable effortless upgrades to higher transmission speeds in data centers when paired with our trunk cables. They are most often employed for patching operations inside a cabinet. MTP® cabling is a cost-effective substitute for labor-intensive field termination, designed for high-density fiber routing in facilities that require space efficiency and reduced cable management complexity.

OM5 fibers are fully compliant with industry standards, meeting all OM3 and OM4 criteria, along with an added requirement for Differential Mode Delay (DMD) to offset both modal and chromatic dispersion. They also feature additional bandwidth testing at 953 nm to support longer distances when using SWDM technology. OM5 fibers are suited for data centers needing rapid infrastructure deployment with extended reach while preserving bandwidth across the network.

Please note: US Conec MTP® connectors fully adhere to MPO standards, offering unique patented elements, improved precision, proven durability, and substantial performance gains over conventional MPO connectors.

MTP Jumpers Advantage Specifications

Connector A：US Conec MTP® Elite Female (Pinless)
Connector B：US Conec MTP® Elite Female (Pinless)
Polish Type：UPC to UPC
Fiber Mode：OM5 50/125μm
Wavelength：850/1300nm
Fiber Count：24 Fibers
Polarity：Type A
Cable Outside Diameter (OD)：3.0mm
Cable Jacket：Plenum (OFNP)
Min. Bend Radius (Optical Fiber)：7.5mm
Min. Bend Radius (Fiber Cable)：20/10D (Dynamic/Static)
Connector Durability：500 times
Tensile Strength：80/240N (Long/Short Term)
Insertion Loss：0.35dB Max (0.15dB Typ.)
Return Loss：≥20dB
Attenuation at 850nm：≤2.3dB/km
Attenuation at 1300nm：≤0.6dB/km
Operating Temperature：-10 to 60°C (14 to 140℉)
Storage Temperature：-10 to 70°C (14 to 158℉)
*MTP is a registered trademark of US Conec Ltd.

MTP Patch Cable Polarity

The MTP® 24-fiber Type A cable is a high-density fiber optic assembly designed for efficient backbone cabling in data centers. It features a straight-through (one-to-one) polarity configuration, meaning that fiber position 1 at one connector end is directly aligned with fiber position 1 at the other end, and so on through all 24 fibers.

mtp 24 jumper Key Features:

Structure and Components
Connector type: MTP® (US Conec compliant), 24-fiber version
Fiber count: 24 optical fibers arranged in a single high-density ferrule
Polarity: Type A (straight-through)
Cable jacket: Usually available in OFNR, OFNP, or LSZH ratings, color-coded by fiber type (e.g., aqua for OM3/OM4, yellow for OS2)

Application
Backbone cabling: Used to connect high-density trunk cables between distribution frames, patch panels, or MTP® cassettes
Data center environments: Supports parallel optics and high-speed applications, such as 100G, 200G, and 400G Ethernet
Migration-ready: Compatible with structured cabling systems for easy transition to higher data rates without major re-cabling

Key Advantages
High density: 24 fibers in a single connector reduce the number of cables needed
Fast deployment: Factory-terminated and tested for low loss and quick installation
Polarity simplicity: Type A provides straightforward fiber mapping, making it easy to manage in certain structured cabling designs

MTP Jumpers Advantage

• 100% use low-loss connectors
• Each MPO patch cord is fully tested for insertion loss & return loss, 100% tested, and batch goods are not sloppy
• Each line guarantees 3D geometric dimensions and end face integrity, imported equipment measures 3D, and dust-free workshops ensure cleanliness
• Affordable price, quality assurance, source manufacturers take both quality and price into consideration
• All materials have passed REACH/ROHS environmental protection requirements and are of export quality
• Adequate inventory, complete materials, and efficient production
• Customization of special specification MPO patch cords, fast delivery

MTP Jumpers Data Center Solutions

MTP Jumpers Application

High-speed interconnection in data centers

It is used for direct connection of 40G/100G optical modules, supports 400G high-speed transmission, and can improve wiring density and transmission efficiency. For example, 400G QSFP-DD DR4 optical modules can be directly connected through MPO/MTP-8 multimode fiber jumpers. ‌

High-density wiring scenarios

In the backbone wiring of data centers, MTP/MPO trunk fiber jumpers are used in conjunction with adapter modules to achieve interconnection and cross-connection between devices, saving 45% of wiring space. Branch jumpers are used to connect devices with different rates (such as 10G and 40/100G devices). ‌

100G/400G transmission expansion

Supports branch connection of 100G QSFP28 optical modules to 4 25G SFP28 optical modules, or interconnection of 100G CFP optical modules to another CFP. ‌

Fiber-to-Building Applications

It is used for fiber-to-the-building (FTTB) wiring to meet the needs of high-density fiber access.

MTP Jumpers Test Series

MTP Jumpers Polarity Test Process

‌End face cleaning: Use special equipment to remove end face contaminants to avoid affecting the test accuracy. ‌
Morphology detection: Analyze the end face microstructure through 3D imaging technology to detect surface roughness, scratches and other defects. ‌
Insertion loss test: Measure the contact loss between the fiber end face and the connector ferrule to evaluate the signal transmission quality. ‌
Polarity verification: Confirm the correspondence between the number of fiber cores and the connector guide hole to prevent communication failure caused by wrong connection. ‌

MTP Jumpers Test Key Indicators

Cleaning efficiency: It must reach more than 98% to ensure that there are no residual stains on the end face. ‌
‌Detection accuracy: The resolution of 3D morphology detection must be less than 1.5μ, and the insertion loss error must be controlled within 0.3dB. ‌
Test time: It takes about 10 seconds to detect a single fiber core of a 12-core MPO jumper, and the overall test takes about 2 minutes.

MTP Jumpers Test Common Problems

Pollution sensitivity: Tiny particles on the end face will cause increased loss, and non-contact cleaning methods are required to protect the end face. ‌ ‌