Cisco technology, inc. (20240345180). SYSTEM AND METHOD FOR DETERMINING CABLE PERFORMANCE BASED ON FREQUENCY DEPENDENT SKEW simplified abstract

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SYSTEM AND METHOD FOR DETERMINING CABLE PERFORMANCE BASED ON FREQUENCY DEPENDENT SKEW

Organization Name

cisco technology, inc.

Inventor(s)

David Nozadze of San Jose CA (US)

Mike Sapozhnikov of San Jose CA (US)

Upen Reddy Kareti of Union City CA (US)

Amendra Koul of San Francisco CA (US)

Joel Richard Goergen of Soulsbyville CA (US)

SYSTEM AND METHOD FOR DETERMINING CABLE PERFORMANCE BASED ON FREQUENCY DEPENDENT SKEW - A simplified explanation of the abstract

This abstract first appeared for US patent application 20240345180 titled 'SYSTEM AND METHOD FOR DETERMINING CABLE PERFORMANCE BASED ON FREQUENCY DEPENDENT SKEW

Simplified Explanation

The method described in the patent application involves determining the skew values of cables, which indicate the time of signal propagation at different signal frequency values. These skew values are then used to determine skew behavior property values for each cable, which are in turn used to calculate performance metric values. By analyzing the relationship between skew values, signal frequency values, and performance metric values, electronic components can be connected using new cables.

  • The method involves analyzing skew values of cables at different signal frequency values.
  • Skew behavior property values are determined based on the skew values.
  • Performance metric values are calculated for each skew behavior property value.
  • The relationship between skew values, signal frequency values, and performance metric values is analyzed.
  • Electronic components are connected using new cables based on this relationship.

Key Features and Innovation

  • Determining skew values of cables at different signal frequency values.
  • Analyzing skew behavior property values for each cable.
  • Calculating performance metric values based on the skew behavior property values.
  • Establishing a relationship between skew values, signal frequency values, and performance metric values.
  • Using this relationship to connect electronic components with new cables.

Potential Applications

This technology can be applied in various industries where precise signal propagation timing is crucial, such as telecommunications, data centers, and high-speed computing.

Problems Solved

This technology addresses the challenge of ensuring accurate signal propagation timing between electronic components connected by cables.

Benefits

  • Improved signal propagation timing accuracy.
  • Enhanced performance of electronic systems.
  • Better reliability in data transmission.

Commercial Applications

  • Telecommunications industry for high-speed data transmission.
  • Data centers for efficient data processing.
  • High-speed computing for improved system performance.

Prior Art

Readers can explore prior research on signal propagation timing analysis, cable skew values, and electronic component connections in related patents and academic publications.

Frequently Updated Research

Stay updated on advancements in signal propagation timing analysis, cable technology, and electronic component connections to enhance the application of this technology.

Questions about Cable Skew Analysis

How does cable skew analysis impact signal transmission efficiency?

Cable skew analysis helps optimize signal propagation timing, leading to more efficient data transmission between electronic components.

What are the key factors to consider when analyzing cable skew values?

Key factors to consider include signal frequency values, skew behavior property values, and performance metric values in determining the relationship between skew values and signal frequency values.


Original Abstract Submitted

presented herein is a method comprising: determining skew values of cables, each skew value indicating a time of signal propagation along a respective cable at a respective signal frequency value, and the skew values being frequency dependent and varying at signal frequency values; determining skew behavior property values for each cable based on the skew values; determining a performance metric value for each skew behavior property value; determining a relationship between the skew values and the signal frequency values at each performance metric value based on the performance metric value for each skew behavior property value; and coupling a first electronic component and a second electronic component to one another using a new cable based on the relationship between the skew values and the signal frequency values at each performance metric value.