In the z-axis–modulation technique,

In the z-axis–modulation technique,
the system determines the tube current
by using the patient’s localizer radiograph
projection data and a set of empirically
determined noise prediction coefficients
by using the reference technique
(Fig 2). The reference technique comprises
an arbitrary 2.5-mm-thick section
obtained at the selected peak voltage and
100 mAs for transverse reconstruction
with a standard reconstruction algorithm.
The projection data from a single localizer
radiograph can be used to determine the
density, size, and shape information of the
patient (4,5). The total projection attenuation
data of a single localizer radiograph
contain the patient’s density and size information
about the projection area,
whereas the amplitude and area of the projection
contain the patient’s shape information,
which gives an estimate of the patient’s
elliptic asymmetry expressed as an
oval ratio at a given z-axis position. The
oval ratio is the ratio of the a and b parameters
(lengths of the long and short axes) of
an ellipse. The ellipse parameters can be
determined for the patient by using the
equation for the area of an ellipse. The
measured projection area and amplitude
from the localizer radiograph give the area
and the length of one axis, a, of the ellipse,
allowing the length of the other axis, b, to
be calculated. These characteristics of the
localizer radiograph predict the amount of
x-rays that will reach the detector for a
specified technique and, hence, determine
the image standard deviation due to x-ray
noise for a given reconstruction algorithm.
The predicted x-ray noise at a given z-axis
position for the reference technique (ie,
reference noise) is calculated from the projection
area and oval ratio from the localizer
radiograph by using the polynomial
coefficients that were determined from the
noise measurements in a set of phantoms
representing a wide range of patient sizes
and shapes.