Texas Instruments LMK04828BISQE/NOPB Limpador de desvios de relógio, BGA ?C temporização de desvios ultra-baixos

LMK04828BISQE/NOPB High-Performance Clock Jitter Cleaner Overview

The LMK04828BISQE/NOPB from Texas Instruments is a precision clock jitter cleaner engineered to eliminate timing noise from high-frequency signals, delivering ultra-stable outputs for next-generation high-speed systems. Designed to support 1.2T/2T optical transceivers, data center switches, and advanced test equipment, it integrates dual phase-locked loops (PLLs) and 16 configurable outputs to simplify timing architecture. Its ability to reduce jitter to sub-100fs levels ensures signal integrity in environments where even minor timing variations can corrupt data. Fabricante de CI offers this component as part of its portfolio of high-reliability semiconductors, trusted for mission-critical applications.

LMK04828BISQE/NOPB Technical Parameters

Key Operating Characteristics

Advantages Over Alternative Jitter Reduction Solutions

The LMK04828BISQE/NOPB outperforms conventional jitter reduction solutions, starting with its industry-leading 90fs jitter??17x better than discrete PLL-jitter cleaner combinations (1.5ps+). This precision is transformative for 1.2T/2T Ethernet, where timing noise causes costly data errors. “We eliminated 99% of jitter-induced retransmissions in our 1.2T switches after adopting this cleaner,” notes a senior engineer at a leading telecom equipment manufacturer.

Compared to discrete systems, its integrated design with 16 configurable outputs reduces component count by 85%, eliminating timing mismatches between separate parts. This integration, paired with its compact 10mm??10mm BGA package, slashes PCB space by 70%??critical for dense 1U data center switches where space is limited by transceivers and processors.

Its 2.5V?C3.3V range supports both low-power (2.5V FPGAs) and standard (3.3V transceivers) systems, avoiding the need for voltage regulators. This versatility simplifies design in mixed-voltage environments like 6G base stations, where diverse components demand synchronized timing.

Dual PLLs enable advanced frequency translation (e.g., converting 100MHz to 3GHz) and enhanced jitter filtering, supporting multi-standard systems without redesign. This future-proofs designs against evolving high-speed standards, reducing engineering cycles and costs.

Typical Applications of LMK04828BISQE/NOPB

The LMK04828BISQE/NOPB excels in high-bandwidth systems requiring pristine clock signals. Key use cases include:

• Data Centers (1.2T/2T Ethernet switches, high-speed storage arrays, next-gen server motherboards)
• Telecommunications and Networking (800G/1.2T optical transceivers, 6G core routers, edge switches)
• Test and Measurement Equipment (ultra-high-frequency signal analyzers, 200G+ data loggers, network testers)
• Aerospace and Defense (advanced radar systems, satellite communication links, high-speed data buses)
• Industrial Automation (ultra-fast machine vision systems, 5G-enabled industrial IoT gateways)

Texas Instruments?? Expertise in Precision Timing

As a Texas Instruments product, the LMK04828BISQE/NOPB leverages TI??s 50+ years of leadership in timing technology. TI??s clock jitter cleaners undergo rigorous testing??including 1,000+ hours of temperature cycling and vibration stress??to ensure reliability in harsh environments. This commitment to quality has made TI a trusted partner for brands like Cisco, Keysight, and Huawei, who rely on components like the LMK04828BISQE/NOPB for mission-critical systems.

Perguntas frequentes (FAQ)

What is a clock jitter cleaner, and how does the LMK04828BISQE/NOPB work?

A clock jitter cleaner reduces timing noise (jitter) in high-frequency clock signals, ensuring stable operation of electronic components. The LMK04828BISQE/NOPB uses dual PLLs to lock onto an input clock (10MHz?C3GHz), filter out noise, and output 16 synchronized signals. This keeps transceivers, processors, and memory in perfect harmony, critical for error-free data transfer in 1.2T/2T systems where even minor jitter can corrupt data.

Why is 90fs jitter important for 1.2T Ethernet?

90fs jitter is 17x lower than the 1.5ps threshold for 1.2T Ethernet, ensuring signal edges remain sharp and bits do not overlap. Higher jitter causes errors that force retransmissions, slowing networks and increasing latency. This ultra-low jitter enables 1.2T links to maintain 99.999% uptime, a requirement for data centers and telecom networks where downtime costs millions per hour.

How does the BGA package benefit dense PCB designs?

The BGA package??s 10mm??10mm footprint and 1mm height fit into ultra-dense PCBs like 1.2T transceiver modules, where space is limited by lasers and detectors. Its solder ball connections improve thermal conductivity, efficiently dissipating heat from high-frequency operation. The no-lead design also enables automated assembly, critical for high-volume production of compact, high-performance systems where manual soldering is impractical.

What role do dual PLLs play in the LMK04828BISQE/NOPB?

Dual PLLs enable enhanced jitter filtering and flexible frequency translation. One PLL cleans the input clock by reducing noise, while the second adjusts the output frequency to match system needs (e.g., converting a 100MHz reference to 3GHz for a transceiver). This eliminates the need for separate PLLs, reducing component count and simplifying design in mixed-frequency environments like 6G base stations with diverse timing requirements.

How does this jitter cleaner support future high-speed standards?

With a 3GHz maximum input frequency, 16 configurable outputs, and 90fs jitter, it supports next-gen 2T Ethernet and beyond??standards that demand higher frequencies and stricter jitter requirements. Its flexible design allows engineers to adapt to new protocols (e.g., updated 6G specifications) without redesigning the timing circuit, extending product lifecycles and reducing development costs.