Vendor: 1-VIA Category: PLL

14GHz Integer-N High-Speed PLL

1-VIA’s broad portfolio of general-purpose and optimized LC-PLLs offer a wide range of clocking solutions.

Overview

1-VIA’s broad portfolio of general-purpose and optimized LC-PLLs offer a wide range of clocking solutions.

The Integer-N high-speed PLL creates quadrature clocks with good duty cycle and excellent jitter characteristics for high-speed, source-synchronous interfaces and other high-speed logic applications.

The PLL is implemented using 1-VIA’s proprietary architecture, utilizing an integrated Low-Dropout (LDO) regulator and bandgap reference generator. This architecture helps achieve exceptional jitter performance whilst also reducing power consumption.

Key features

  • Type II hybrid Integer-N LC-PLL
  • Quadrature clocks at 14GHz and 7GHz
  • Fast locking
  • Low-power and ultra-low-jitter (<50fs-rms)
  • Analog and digital lock-detector for calibration and DSP purposes
  • Auto-calibration at start-up and “in background” for PVT drift

Block Diagram

Benefits

  • Wide functional range allows all frequencies in a system to be synthesized with one PLL macro
  • Low area on chip -- keepouts = DRC limit in most cases
  • No external components required
  • No additional supply decoupling required
  • Self biased and automatically adjusts for any input frequency, so no complicated programming is required

Applications

  • Artificial Intelligence (AI)
  • Internet of Things (IoT)
  • Medical
  • Analogue-to-Digital Converter (ADC)
  • RF ASICs
  • Automotive
  • Wireless
  • Digital-to-Analog Converter (DAC)
  • Mixed-signal ASICs
  • SoCs
  • SerDes

What’s Included?

  • Datasheet
  • Characterization report
  • Layout view (GDSII)
  • Abstract view (LEF)
  • Behavioural model (VerilogA)
  • Integration guidelines and support

Silicon Options

Foundry Node Process Maturity
TSMC 55nm GP

Specifications

Identity

Part Number
14GHz Integer-N High-Speed PLL
Vendor
1-VIA
Type
Silicon IP

Files

Note: some files may require an NDA depending on provider policy.

Provider

HQ: UK

Learn more about PLL IP core

Creating a Frequency Plan for a System using a PLL

How do you ensure that every part of a system receives the clock it needs—without wasting power or sacrificing performance? The answer lies in creating a well-structured frequency plan built around a PLL.

Specifying a PLL Part 3: Jitter Budgeting for Synthesis

This white paper is aimed at system architects and physical implementation leaders working on the design of SoCs. It can be confusing to understand the impact of different jitter sources and how to calculate a jitter budget when specifying a digital system. This white paper explains how jitter changes the period of a clock and how to ensure that jitter has correctly been accounted for in the calculations for timing closure.

Specifying a PLL Part 2: Jitter Basics

This article explains a some of the key terminology and parameters commonly used to describe jitter. It will also help clarify the most important parameters for a some PLL applications, allowing the designer to better understand what is required from a PLL.

Specifying a PLL Part 1: Calculating PLL Clock Spur Requirements from ADC or DAC SFDR

In high end RF systems, such as 5G radios, the requirements are so stringent that the source of this strongest unwanted tone can be the PLL. This article outlines how spurs in the input clock to the ADC or DAC may limit the SFDR. This in turn will set the requirements for the spurs for the input clock (from a PLL), in order to achieve a specific SFDR.

Achieving Groundbreaking Performance with a Digital PLL

This article compares analog, first-generation digital, and second-generation digital PLLs. It evaluates which type of PLL may be best in which situation. It further discloses a roadmap into other application areas, including general purpose / logic clocking, and regular low-jitter PLLs.

Frequently asked questions about PLL IP cores

What is 14GHz Integer-N High-Speed PLL?

14GHz Integer-N High-Speed PLL is a PLL IP core from 1-VIA listed on Semi IP Hub. It is listed with support for tsmc.

How should engineers evaluate this PLL?

Engineers should review the overview, key features, supported foundries and nodes, maturity, deliverables, and provider information before shortlisting this PLL IP.

Can this semiconductor IP be compared with similar products?

Yes. Buyers can compare this product with similar semiconductor IP cores or IP families based on category, provider, process options, and structured technical specifications.

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