Reliability Growth Analysis (RGA) is a method to assess the reliability of systems or products during the development and testing phases. RGA tracks the rate at which reliability improves over time, typically as design changes, fixes, or process improvements are implemented. The primary objective is to measure the system or product’s failure behavior and predict how it will perform once the product is fully mature or operational.
The Crow-AMSAA or Non-Homogeneous Poisson Process (NHPP) model is a statistical model used to track reliability improvements over time. This model is particularly useful for analyzing failure data in systems where the failure rate changes due to improvements or corrective actions during the development or operational phase.
In a NHPP, the failure rate changes over time, increasing or decreasing depending on actions taken to improve reliability. Failures follow a Poisson process, but the rate at which they occur changes with time, hence “non-homogeneous.”
The failure intensity (rate of failures per time unit) is modeled as a power function of time:
λ(t) = β ⋅ tβ − 1
where:
The cumulative number of failures up to time t is given by:
N(t) = λ0 ⋅ tβ
Where:
The Shape Parameter (β) indicates whether the system is improving or deteriorating:
If β > 1, failures are increasing over time, indicating that reliability is worsening.
If β < 1, failures are decreasing, indicating that reliability is improving over time.
β = 1 implies a constant failure rate (no growth or degradation).
The Scale Parameter (λ0) is related to the initial failure rate.
The Piecewise Weibull NHPP model is an extension of the standard NHPP model that includes different segments or phases of time that follow separate Weibull failure distributions. This model is particularly useful when a system experiences changes in failure behavior over different development phases, such as the initial, interim and final phases of a development process.
The Weibull intensity function for each time segment i is modeled as:
$$ \lambda_i(t) = \frac{\beta_i}{\eta_i} \left( \frac{t - t_{i-1}}{\eta_i} \right)^{\beta_i - 1} $$
Where:
The Piecewise Weibull NHPP with Change Point Detection is an advanced model to identify changes in failure behavior and model system reliability. This method builds on the Piecewise Weibull NHPP model by introducing the concept of change points, which represent the time when the underlying failure behavior changes. Detection of change points involves statistical techniques that analyze failure data to automatically identify when the behavior changes, allowing for a more precise segmentation of the model into different Weibull distributions.
The Duane Model is another graphical method to track and visualize the reliability improvement of a product or system over time. The Duane Plot is a log-log plot that shows the cumulative failure rate or Mean Time Between Failures (MTBF) versus time, helping to assess whether reliability is improving, stabilizing, or worsening over time.
RGA provides a quantitative framework for understanding how a system’s reliability changes over time and guides decisions for further improvements based on observed failure patterns.