/** * Get the mean square error of the y value with respect to the fitted line. The square root of * this number gives an indication of the uncertainty in y value estimates under certain * assumptions about the error distribution. * * @return the mean square error of the y value with respect to the fitted line */ public synchronized double getMeanSquareOrdinateError() { performFitIfNeeded(); final double slope = _slope; final double intercept = _intercept; final double xyMean = _xyStats.mean(); final double xxMean = _xxStats.mean(); final double yyMean = _yyStats.mean(); return yyMean - 2 * slope * xyMean + slope * slope * xxMean - intercept * intercept; }
/** Calculate the slope and intercept. */ protected synchronized void performFit() { final double xMean = _xStats.mean(); final double yMean = _yStats.mean(); final double xyMean = _xyStats.mean(); final double xxMean = _xxStats.mean(); final double yyMean = _yyStats.mean(); _slope = (xyMean - xMean * yMean) / (xxMean - xMean * xMean); _intercept = yMean - _slope * xMean; _correlationCoefficient = (xyMean - xMean * yMean) / Math.sqrt((xxMean - xMean * xMean) * (yyMean - yMean * yMean)); _needsUpdate = false; }
/** * Generate a string representation of the linear equation. * * @return a string representation of the linear equation */ public synchronized String toString() { performFitIfNeeded(); StringBuffer buffer = new StringBuffer(); buffer.append("y = " + _slope + " * x + " + _intercept); buffer.append("\n" + "r = " + _correlationCoefficient); buffer.append("\n" + "<x> = " + _xStats.mean() + ", <y> = " + _yStats.mean()); buffer.append( "\n" + "<xx> = " + _xxStats.mean() + ", <xy> = " + _xyStats.mean() + ", <yy> = " + _yyStats.mean()); return buffer.toString(); }