Statistical Methods For Mineral Engineers ✓
If $X$ is the vector of measured variables and $V$ is the variance-covariance matrix of measurements, we find the adjusted values $\hat{X}$ that minimize:
In the world of mineral engineering, decisions have billion-dollar consequences. A mill that operates at 85% recovery instead of 90% can render a deposit uneconomical. A misinterpreted assay grid can lead to the development of a barren hill. Unlike chemical engineering (which deals with pure reactants) or mechanical engineering (which deals with deterministic tolerances), mineral engineering must contend with heterogeneity .
Where $p$ is the probability of recovery (the metal reporting to concentrate). Many flotation recovery curves follow a sigmoidal shape. The Hill equation (borrowed from biochemistry) models recovery as a function of residence time: Statistical Methods For Mineral Engineers
$$ \gamma(h) = \frac{1}{2N(h)} \sum_{i=1}^{N(h)} [Z(x_i) - Z(x_i + h)]^2 $$
You are designing a sampling protocol for a leach feed. The grind size is $P_{80} = 75 \mu m$. You take a 200g pulp for analysis. The variance is acceptable. Now you need to sample crushed ore at $P_{80} = 10mm$ (10,000 $\mu m$). The particle size ratio is $10,000 / 75 = 133$. The mass required must increase by $133^3 \approx 2.35 \text{ million}$ times. $200g \times 2,350,000 = 470,000 kg$. If $X$ is the vector of measured variables
Statistically, we have redundant data. You have 3 assays (Feed, Con, Tail) and 2 flow rates (Feed, Tail). The system is over-determined . Modern metallurgical accounting uses minimization of weighted sum of squares to adjust measurements so they obey the conservation of mass (tonnage and metal).
Modern mineral engineering is no longer about "the best guess of the chief metallurgist." It is about probabilistic forecasting , quantified risk , and data-driven optimization . Engineers who ignore statistics are not practicing engineering; they are gambling. Those who master the variogram, Gy’s formula, and Bayesian updating will be the ones who unlock value from complex orebodies in a volatile commodity market. For mineral engineers
For mineral engineers, this is revolutionary.