O o d h e a d p u b L i s h I n g L i m I t e d

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Sampling errors:
invariably these result from inadequate design of
sampling systems.
2.
Differences in fundamental assumptions:
in the case of wool fibre
fineness, different assumptions about the geometry of the fibre by different
instrumental methods may lead to bias.
3.
Personal errors:
bias can also be the result of blind prejudice. Most of
Table 2.4 Defining the precision of analytical methods
Terms
Definition
Absolute standard deviation


s
x
x
N
i
N
i
  =

(

–  )
– 1
=1
2
Σ
Relative standard deviation


RSD =
s
x
Standard deviation of the mean


s
s
N
m
  =
Coefficient of variation


CV =
   100
s
x
×
Variance of the mean

  s
m
2
Confidence level (95%)


CL =   1.96
m
2
±
s
x
i
= numerical value of the
ith measurement.
  x
= the mean of
N measurements =


Σ
i
N
i
x
N
=1

Source: P.J. Sommerville,
Technical & Commercial Requirements of Wool
Testing Systems, AWTA Ltd Newsletter, September 2001.
© 2009 Woodhead Publishing Limited

The objective measurement of wool fibre quality
29
us, however honest, have a natural tendency to estimate readings in a
direction that improves the precision of a set of results, or causes the
results to fall closer to a preconceived notion of the true value.
4.
Instrumental errors:
bias can be caused by instrument drift, or by
assumptions made by the technology used in the instrument.
5.
Method errors:
generally this type of bias is the result of a failure to
maintain rigid control over the environmental conditions that impact
upon the measurement.
6.
Interferences:
bias can also be caused by interferences arising from
other constituents in the sample.
Bias may be constant over the range of variation of the characteristic
being measured, or it may vary over this range. One of the objectives of
standardising wool testing systems is the elimination or at least the minimisation
of bias. Where bias cannot be eliminated, provided it is not level dependent,
the measurement technology may still be useful.
2.5.3
Sensitivity
The sensitivity of an instrument or a testing system refers to its ability to
discriminate between small differences in the material being analysed.
Commonly three factors limit sensitivity:
• the slope of an instrument’s calibration curve;
• the precision of the instrument; and
• the error in the sampling system.
2.5.4
Detection limit
The detection limit is a minimum value of the characteristic being measured
that can be detected at a known confidence level. This is not an important
issue, for example, when measuring mean fibre diameter, because wool
fibres never approach zero fineness, and most measurements are conducted
within ranges that exceed the probable detection limit by factors greater than
three.
2.5.5
Range
The useful range of an analytical method can be defined as the lowest point
at which a measurement can be made (the detection limit or the LOQ), to the
point at which the calibration departs from linearity (LOL). However, some
measurement systems have non-linear calibration functions. The useful range
in these instances is more difficult to define.
© 2009 Woodhead Publishing Limited

Advances in wool technology
30
2.5.6
Selectivity
Selectivity refers to the degree to which the analytical method is free from
interferences by other species in the sample matrix. This is generally not a
major issue when testing wool. However, as indicated previously, it may be
an issue for measurement of fibre diameter if extraneous synthetic fibres or
very fine vegetable matter is present in the sample.

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