HyperLynx Power Integrity PCB design analysis software solution

HyperLynx power integrity

Power integrity (PI) analysis is an essential part of modern electronic design. The ever-increasing number of voltages being used by ICs, in addition to dramatic increases in power consumption, make proper power delivery an exceedingly difficult task.

The importance of Power Integrity

High layer counts, tighter margins and lower voltages coupled with increasing power consumption makes Power Integrity analysis an essential component of modern system design. With inadequate power delivery, components can experience logic and signal integrity problems that can cause a board to fail.

Good PCB Power Integrity (PI) is crucial because it ensures electronic circuits operate reliably and efficiently. This is especially true with today's high power, low voltage IC's. Good PCB PI helps with:

  • Stable operation: Power integrity ensures that stable and clean power is delivered to all components. Variations or noise in the power supply can cause components to malfunction or behave unpredictably.
  • Reduced noise and interference: A well-designed power distribution network helps minimize coupling between signals. This is especially important in high-speed circuits where even small amounts of noise can disrupt operation.
  • Thermal management: Proper power distribution helps manage heat dissipation. Poor PI design can lead to overheating that can damage components or the board itself. Signal Integrity: Power integrity directly affects signal integrity because the same system that delivers power to components also provides a return path for signals. If the power delivery network isn’t well-designed, it can lead to signal degradation through crosstalk or return path coupling, which can impair the performance of the circuit.
  • Component longevity: Stable power delivery reduces the stress on electronic components, which can extend their lifespan and reduce the likelihood of failures.
  • EMI Compliance and reliability: Many industries have strict regulatory requirements for product emissions. Ensuring good power integrity helps meet these standards and enhances the reliability of the final product.

The collection of interconnect and components that starts with the Voltage Regulator Module (VRM) and ends at the IC power pins is known as the Power Distribution Network (PDN). Proper design and analysis of power distribution networks is key to achieving stable performance and maintaining overall system health.

There are two fundamental forms of power integrity analysis:

  • DC Power Integrity (DC PI) analyzes PDN behavior under steady-state conditions. It calculates IR drop and current density to ensure that adequate voltage is supplied to IC power pins and that current isn't concentrated in ways that cause thermal stresses that might damage the system. DC PI primarily focuses on power supply components, power planes and associated stitching vias that allow power to flow from layer to layer.
  • AC Power Integrity (AC PI) analyzes PDN behavior under transient conditions due to fluctuations in power demanded by ICs as a result of internal switching activity. These rapid, high-frequency events create instantaneous demands for power that must be serviced by a hierarchy of decoupling capacitors, because the power supply itself is electrically too far away. AC PI primarily focuses on the power planes, stitching vias, decoupling capacitor locations and values, capacitor fanout and the locations of IC power pins.

Power integrity effects on signal integrity

The interaction between PI and SI is often complicated and confusing. With single-ended DDR busses reaching the same data rates as many popular differential SerDes channels, gaining a better understanding of this interaction becomes crucial for a modern designer. Explore our examples of how power and signal integrity interact with each other, and examine some of the possible means of mitigation.

hyperlynx power integrity comparison with signal integrity for PCB analysis

Products