ISO/TR 16153:2023

TECHNICAL ISO/TR
REPORT 16153
Second edition
2023-02
Determination of uncertainty for
volume measurements of a piston-
operated volumetric apparatus using
a photometric method
Détermination de l’incertitude de mesure pour les mesurages
volumétriques des appareils volumétriques à piston au moyen de la
méthode photométrique
Reference number
ISO/TR 16153:2023(E)
© ISO 2023

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ISO/TR 16153:2023(E)
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ISO/TR 16153:2023(E)
Contents Page
Foreword .iv
Introduction .v
1 S c op e . 1
2 Nor m at i ve r ef er enc e s . 1
3 Terms and definitions . 1
4 Modelling the measurement.1
5 G eneral procedure for the uncertainty calculation . 4
6 S tandard uncertainty components associated with the measuring system
(photometric measurement procedure) . 4
6.1 G eneral information on the estimation of standard uncertainty components . 4
6.2 S tandard uncertainty of the copper(II) chloride solution volume . 5
6.3 S tandard uncertainty of the cuvette mixture absorbance at 520 nm . 5
6.4 S tandard uncertainty of the cuvette starting absorbance at 730 nm . 6
6.5 S tandard uncertainty of the cuvette starting absorbance at 520 nm . 6
6.6 S tandard uncertainty of the volume of Ponceau S and copper(II) choloride
solutions used in calibrators . 7
6.7 S tandard uncertainty of the absorbances of the calibrator solutions . 7
7 S tandard uncertainty components associated with the POVA . 9
7.1 S tandard uncertainty of the resolution . 9
7.2 S tandard uncertainty of the setting . 9
7.3 S tandard uncertainty related to air cushion effects . 9
7.4 S tandard uncertainty of the cubic expansion coefficient. 9
8 S tandard uncertainty components associated with the liquid delivery process .10
8.1 R epeatability (experimental standard deviation) . 10
8.2 Reproducibility . 10
9 C ombined standard uncertainty of measurement associated with the systematic
error of mean volume .11
10 Sensitivity coefficients .12
11 Coverage factor k . .13
12 Expanded uncertainty of measurement associated with the volume V .14
13 Example for determining the uncertainty of the volume measurement of POVA .14
13.1 Measurement conditions . 14
13.2 Results . . 16
13.2.1 Standard uncertainty of the POVA mean volume . 16
13.2.2 Expanded uncertainty of the measurement . 17
13.2.3 Result of measurement . 17
13.2.4 Uncertainty in use and corrections for pressure changes . 17
13.2.5 General remarks . 17
13.2.6 Note on the conformity with ISO/IEC Guide 98-3 . 17
Annex A (informative) Approaches for the estimation of uncertainty in use of a single
delivered volume .19
Annex B (informative) Volume correction due to pressure changes .22
Bibliography .24
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ISO/TR 16153:2023(E)
Foreword
ISO (the International Organization for Standardization) is a worldwide federation of national standards
bodies (ISO member bodies). The work of preparing International Standards is normally carried out
through ISO technical committees. Each member body interested in a subject for which a technical
committee has been established has the right to be represented on that committee. International
organizations, governmental and non-governmental, in liaison with ISO, also take part in the work.
ISO collaborates closely with the International Electrotechnical Commission (IEC) on all matters of
electrotechnical standardization.
The procedures used to develop this document and those intended for its further maintenance are
described in the ISO/IEC Directives, Part 1. In particular, the different approval criteria needed for the
different types of ISO documents should be noted. This document was drafted in accordance with the
editorial rules of the ISO/IEC Directives, Part 2 (see www.iso.org/directives).
Attention is drawn to the possibility that some of the elements of this document may be the subject of
patent rights. ISO shall not be held responsible for identifying any or all such patent rights. Details of
any patent rights identified during the development of the document will be in the Introduction and/or
on the ISO list of patent declarations received (see www.iso.org/patents).
Any trade name used in this document is information given for the convenience of users and does not
constitute an endorsement.
For an explanation of the voluntary nature of standards, the meaning of ISO specific terms and
expressions related to conformity assessment, as well as information about ISO's adherence to
the World Trade Organization (WTO) principles in the Technical Barriers to Trade (TBT), see
www.iso.org/iso/foreword.html.
This document was prepared by Technical Committee ISO/TC 48, Laboratory equipment.
This second edition cancels and replaces the first edition (ISO/TR 16153:2004), which has been
technically revised.
The main changes are as follows:
— the term “standard deviation of the mean delivered volume” has been replaced in this document by
“repeatability” according to ISO/IEC Guide 99 (VIM);
— a new uncertainty calculation example has been supplied;
— new uncertainty components have been added, namely, reproducibility, air cushion and resolution;
— new Annex A concerning the uncertainty in use of a single delivered volume has been added;
— new Annex B concerning volume correction due to pressure changes has been added.
Any feedback or questions on this document should be directed to the user’s national standards body. A
complete listing of these bodies can be found at www.iso.org/members.html.
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ISO/TR 16153:2023(E)
Introduction
The example given in this document is informative and supports the requirements found in
ISO 8655-8:2022, 9.4 and ISO 8655-7:2022, 4.2, to perform an estimation of measurement uncertainty
when calibrating POVA according to the measurement procedures described in these documents and
the principles of ISO/IEC Guide 98-3.
The revision of this document coincides with a major revision of the ISO 8655 series in 2022, reflecting
the state-of-the-art measurement procedures and approaches for the estimation of measurement
uncertainty.
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TECHNICAL REPORT ISO/TR 16153:2023(E)
Determination of uncertainty for volume measurements
of a piston-operated volumetric apparatus using a
photometric method
1 S cope
This document gives detailed information regarding the evaluation of uncertainty for the photometric
reference measurement procedure specified in ISO 8655-8 and the photometric procedure specified in
ISO 8655-7:2022, Annex B according to ISO/IEC Guide 98-3.
This document also describes the determination of other uncertainty components related to the liquid
delivery process of a piston-operated volumetric apparatus (POVA), e.g. repeatability and handling.
Furthermore, it provides examples for the calculation and application of the uncertainty of the mean
delivered volume and the uncertainty in use of a single delivered volume.
2 Normat ive references
The following documents are referred to in the text in such a way that some or all of their content
constitutes requirements of this document. For dated references, only the edition cited applies. For
undated references, the latest edition of the referenced document (including any amendments) applies.
ISO 8655-1, Piston-operated volumetric apparatus — Part 1: Terminology, general requirements and user
recommendations
3 Terms and definitions
For the purposes of this document, the terms and definitions given in ISO 8655-1 apply.
ISO and IEC maintain terminology databases for use in standardization at the following addresses:
— ISO Online browsing platform: available at https:// www .iso .org/ obp
— IEC Electropedia: available at https:// www .electropedia .org/
4 Modelli ng the measurement
The dual-dye ratiometric photometric measurement procedures described in ISO 8655-7 and ISO 8655-8
use a cuvette containing a copper(II) chloride solution of known volume, which is determined by
a gravimetric method. The POVA under test is used to add an unknown volume of test solution with
known Ponceau S concentration to the cuvette containing CuCl solution. The contents of the cuvette
2
are mixed without removing the cuvette from the light path of the spectrophotometer, and absorbances
at 520 nm and 730 nm are measured before and after the addition of test solution.
Calibrator solutions of CuCl and Ponceau S are prepared, and their absorbance values at 520 nm and
2
730 nm measured. Preparation of the Ponceau S test solutions of different concentrations involves the
preparation of dilutions, which are expressed by the dilution ratio, R. Absorbances of the calibrator
solutions, together with the dilution ratio, R, are used to calculate the calibration constant, K, for a given
concentration of Ponceau S.
The unknown volume of Ponceau S solution delivered by the POVA under test is calculated from the
volume and absorbances of the CuCl solution prior to addition of test solution, the calibration constant
2
K, and the absorbance of the mixture in the cuvette after addition of test solution.
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ISO/TR 16153:2023(E)
The Formula for the total volume V (i) of delivered test solution after the i-th delivery at the test
T
temperature is given by Formula (1):
Ai()− A
M520 C520
AA−
C730 C520
Vi()= V (1)
TC0
Ai()− A
M520 C520
K −
j
AA−
C730 CC520
where
V (i) is the total volume of test solution which has been added to the test cuvette from the first
T
delivery through the i-th delivery;
V is the actual volume of copper(II) chloride solution in the prepared test cuvette at the
C0
start of the test;
K is the calibration constant from Formula (2);
j
A (i) is the absorbance at 520 nm of the cuvette mixture after the i-th delivery of test solution;
M520
A is the absorbance at 520 nm of the copper(II) chloride solution in the cuvette prior to the
C520
first delivery of test solution;
A is the absorbance at 730 nm of the copper(II) chloride solution in the cuvette prior to the
C730
first delivery of test solution.
The calibration constant (K ) for each batch of solutions is calculated using Formula (2). Absorbance
j
values are obtained from the measurements in ISO 8655-8:2022, 8.2.
 AA− 
1
Cal520,j CalC520
K =   (2)
j
 
R AA−
j  CalC730 CalC520 
where
K is the calibration constant for the test-volume-specific calibrator solution [the subscript
j
j refers to the test volume (V )];
S
R is the dilution ratio of the calibrator solution;
j
A is the absorbance of the Ponceau S calibrator solution j at 520 nm;
Cal520,j
A is the absorbance of the CuCl solution at 520 nm;
CalC520 2
A is the absorbance of the CuCl solution at 730 nm.
CalC730 2
The dilution ratio (R) is calculated according to Formula (3).
V
PS
R= (3)
VV+
PS C
where
R is the dilution ratio;
V is the actual measured volume of Ponceau S solution;
PS
V is the actual measured volume of copper(II) chloride solution.
C
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ISO/TR 16153:2023(E)
Formulae (1), (2) and (3) contain nine input variables. Six of these inputs are photometric absorbance
values. Three inputs are liquid volumes at the test temperature and each of these three volumes is
determined by weighing on a balance.
The liquid volumes V , V and V at the test room temperature are calculated according to Formula (4).
C0 PS C
ρ
1  
A
Vm=−()m × ×−1 (4)
LL E  
ρρ− ρ
 
LA B
where
V is the calculated volume at the temperature of the test liquid, in ml;
L
m is the balance indication of the weighing vessel after liquid delivery, in g;
L
m is the balance indication of the weighing vessel before liquid delivery, in g (m = 0 in case the
E E
balance was tared with the weighing vessel);
ρ is the density of air, in g/ml (see Formula (5) below);
A
ρ is the actual or assumed density of the weights used to calibrate the balance, in g/ml;
B
NOTE Stainless steel weights of density 8,0 g/ml are typically used for balance calibration.

ρ is the density of the liquid at the test temperature, in g/ml.
L
Formula (5) for the air density can be used at temperatures between 15 °C and 27 °C:
()0,061×t
0,,348 48×−Ph0 009××e
1
r
ρ =× (5)
A
1 000 t+ 273,15
where
ρ
is the air density, in g/ml;
A
t is the ambient temperature, in °C;
P is the barometric pressure, in hPa;
h is the relative air humidity, in %.
r
−4
The relative uncertainty of Formula (5) is 2,4 × 10 g/ml under the following conditions: barometric
pressure between 600 hPa and 1 100 hPa, ambient temperature between 15 °C and 27 °C, and relative
humidity between 20 % and 80 %.
At other environmental conditions, Formula (5) is replaced with the CIPM-2007 calculations described
in Reference [3].
According to ISO 8655-8, the mean volume is calculated according to Formula (6):
Vn()
T
V = (6)
n
where
V is the mean volume;
V (n) is the total volume of test solution in the cuvette after the n-th delivery (typically, n = 10).
T
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ISO/TR 16153:2023(E)
If a cubic expansion coefficient γ for the POVA is known, it can be applied to correct the dispensed
volume to the reference temperature using Formula (7).
Vi()=×Vi() [(1−−γ tt )] (7)
T,refT Lref
where
V (i) is the total volume of test liquid after the i-th delivery corrected to a reference temperature;
T,ref
γ is the cubic thermal expansion coefficient for the POVA under test;
t is the temperature of the test liquid at the test room temperature;
L
t is the reference temperature for the POVA, typically 20 °C or 27 °C.
ref
5 Gener al procedure for the uncertainty calculation
The evaluation of measurement uncertainty in this document follows ISO/IEC Guide 98-3. The method
has the following steps:
a) Expressing, in mathematical terms, the relationship between the measurand and its input
quantities.
b) Determining the expected value of each input quantity.
c) Determining the standard uncertainty of each input quantity.
d) Determining the degree of freedom for each input quantity.
e) Determining all covariance between the input quantities.
f) Calculating the expected value for the measurand.
g) Calculating the sensitivity coefficient of each input quantity.
h) Calculating the combined standard uncertainty of the measurand.
i) Calculating the effective degrees of freedom of the combined standard uncertainty.
j) Choosing an appropriate coverage factor, k, to achieve the required confidence level.
k) Calculating the expanded uncertainty.
In this document, the uncertainty of the measurement associated with the systematic error of the
mean volume is separated into three different clauses: the uncertainty components associated with
the photometric measuring system (Clause 6), the uncertainty components associated with the device
under test (POVA, Clause 7) and the uncertainty components associated with the liquid delivery process
(Clause 8).
6 Sta ndard uncertainty components associated with the measuring system
(photometric measurement procedure)
6.1 Gener al information on the estimation of standard uncertainty components
It is possible to experimentally estimate the standard uncertainty of measurement, u(x), for a quantity
x, by performing repeated measurements of x under normal laboratory conditions. This is called a
type A evaluation according to ISO/IEC Guide 98-3. The standard deviation of the obtained values is a
measure of the repeatability of the measurement. The standard uncertainty associated with x can be
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ISO/TR 16153:2023(E)
the standard deviation (in the case where a single measurement of x is made), or the standard deviation
of the mean equal to stdev(x)/sqrt(n) (in the case where x is the average of n readings).
See ISO/IEC Guide 98-3:2008,4.2 for more information on type A evaluation of standard uncertainty.
In addition to repeated measurements, the systematic component of the uncertainty of measurement
for a quantity x is estimated by other means. This is called a type B evaluation according to
ISO/IEC Guide 98-3. For example, one can obtain information for that estimation by considering the
manufacturer’s specifications of the POVA (e.g. resolution, linearity, drift, temperature dependence,
etc.).
Often the manufacturer’s specifications are given in the form of an interval covering the measurement
value, with no additional information regarding distribution or coverage. In those cases, the
measurement is assumed to follow a uniform or rectangular distribution. This distribution is
characterized by a constant probability inside the interval while the probability outside the interval is
zero.
The interval can be used to give the variance of x according to Formula (8):
2
()aa−
2 +−
ux()= (8)
12
where
2
u (x) is the variance of quantity x;
a and a
give the upper and lower limits of the interval of the variable x.
+ −
The standard uncertainty, u(x), is given as the square root of the variance.
In addition to uniform rectangular, other distributions are also possible when performing type B
evaluations. See ISO/IEC Guide 98-3:2008, 4.3 for more information on type B evaluations of standard
uncertainty.
6.2 Standar d uncertainty of the copper(II) chloride solution volume
According to ISO 8655-7 and ISO 8655-8, the volume of copper(II) chloride solution (V ) is in the range
C0
of 4,5 ml to 5,5 ml and is within ±0,03 % of the chosen volume. For this example, the maximum specified
error (±0,03 %) is modelled as a rectangular distribution, as shown in Formula (9).
0,000 3
uV()=×V (9)
C0 C0
3
where
u(V ) is the standard uncertainty associated with the volume of the copper(II) chloride solution;
C0
V is the volume of copper(II) chloride solution in the cuvette.
C0
EXAMPLE When V is 5 000 µl, u(V ) is 0,866 0 µl with infinite degrees of freedom based on a rectangular
C0 C0
distribution.
NOTE Formula (4) is used in the measurement of this volume (V ) at the temperature of the absorbance
C0
measurement. The uncertainty of the balances and other test equipment specified in ISO 8655-8 are sufficient to
achieve a 3:1 measurement capability index versus this 0,03 % tolerance when using Formula (4).
6.3 Standar d uncertainty of the cuvette mixture absorbance at 520 nm
The absorbance of the cuvette mixture at 520 nm after the n-th delivery, A (n), in a reference
M520
calibration (n = 10 or greater) is typically in the range of 0,50 to 1,2 absorbance units (AU). The
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ISO/TR 16153:2023(E)
uncertainty of this measurement is dominated by photometric repeatability of the spectrophotometer
(0,01 % relative standard deviation or 0,000 05 AU, whichever is greater). There is also a contribution
from the effect that allowable temperature change has on the chromophore (±0,5 °C rectangular). An
example is given in Formula (10), where there is a relative uncertainty due to repeatability of 0,01 %,
plus the 0,5 °C temperature limit (rectangular), multiplied by the dye sensitivity of 0,000 5 % per °C.
2
05,
22
uA[(nA)]=×()n 0,,000 10+×000 5 (10)
M52M0 520
3
where
u[A (n)] is the standard uncertainty associated with the absorbance of the cuvette mixture at
M520
520 nm;
A (n) is the absorbance of the cuvette mixture at 520 nm.
M520
EXAMPLE For a 5 µl test volume and n = 10 replicates, A (n) is expected to be 0,681 7 AU and u[A (n)]
M520 M520
−4
is 1,197 × 10 AU with 285 degrees of freedom. This is based on an estimate of infinite degrees of freedom for
the rectangular distribution of the temperature range, 30 degrees of freedom for the photometric repeatability,
and applying the Welch-Satterthwaite formula in Clause 11.
6.4 Standar d uncertainty of the cuvette starting absorbance at 730 nm
The starting absorbance of the cuvette at 730 nm before the first delivery (A ) is in the range of
C730
1,0 AU to 1,3 AU. The uncertainty of this measurement is dominated by photometric repeatability of the
spectrophotometer (0,01 % relative standard deviation) and a similar contribution from the effect that
allowable temperature uncertainty (0,1 °C, k = 2) has on the CuCl chromophore.
2
An example is given in Formula (11), where there is a relative uncertainty due to repeatability of 0,01 %,
plus the 0,05 °C temperature uncertainty (k = 1), multiplied by the dye sensitivity of 0,001 65 % per °C.
22 2
uA()=×A 0,,000 10+×001 65 00, 5 (11)
C73C0 730
where
u(A ) is the standard uncertainty associated with the starting absorbance at 730 nm;
C730
A is the starting absorbance of the cuvette at 730 nm.
C730
−4
EXAMPLE When A is 1,098 AU, then u(A ) is 1,423 × 10 AU with 58 degrees of freedom. This is
C730 C730
based on an estimate of 30 degrees of freedom for the temperature uncertainty, 30 degrees of freedom for the
photometric repeatability and applying the Welch-Satterthwaite formula in Clause 11.
6.5 Standar d uncertainty of the cuvette starting absorbance at 520 nm
The starting absorbance of the cuvette at 520 nm before the first delivery (A ) is in the range of
C520
0,015 AU to 0,025 AU. The uncertainty of this measurement is dominated by photometric repeatability
specification of the spectrophotometer (0,000 05 AU standard deviation) and is shown in Formula (12).
The contribution from temperature uncertainty is negligible.
uA()= 0,000 05 (12)
C520
where u(A ) is the standard uncertainty associated with the starting absorbance at 520 nm.
C520
−5
EXAMPLE u(A ) is taken to be 5,000 × 10 AU with 30 degrees of freedom.
C520
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ISO/TR 16153:2023(E)
6.6 Standar d uncertainty of the volume of Ponceau S and copper(II) choloride solutions
used in calibrators
The dilution ratio, R, of the calibrators is calculated according to Formula (3).
In this example, each of these volumes (V and V ) is measured by weighing and calculated at the test
PS C
temperature according to Formula (4). The typical values are in the range of several ml up to several
litres, depending on calibrator solutions.
For V , the relative standard uncertainty of weighing indication is estimated at 0,002 0 % (or better) of
PS
indicated value based on the minimum requirements for balances stated in ISO 8655-8. Two indications
are required for each solution, empty and loaded, so this value appears twice in Formula (13) and twice
in Formula (14).
The uncertainty in density also contributes to uncertainty in V . The two primary contributors are the
PS
standard relative uncertainty (k = 1) of the density meter (0,002 5 %) and the effect that temperature
uncertainty of the liquids has on the density of the Ponceau S solution, which is estimated as 0,001 05 %
(based on 0,021 0 % per °C expansion, and 0,05 °C standard uncertainty in the liquid temperature).
This uncertainty in V is shown in Formula (13).
PS
22 22
uV()=×V 0,,,000  02 ++0 000 02 0 000 025 + 0,000 010 5 (13)
PS PS
where
u(V ) is the standard uncertainty associated with the volume of Ponceau S solution used in the
PS
calibrator solutions;
V is the volume of Ponceau S solution used in the calibrator solutions.
PS
−4
EXAMPLE 1 When V is 5 ml, then u(V ) is 1,959 × 10 ml with 98 degrees of freedom. This is based on an
PS PS
estimate of 30 degrees of freedom for each of the four contributing uncertainties in Formula (13) and applying
the Welch-Satterthwaite formula in Clause 11.
Similarly, the uncertainty in V is calculated as shown in Formula (14):
C
22 22
uV()=×V 0,,,000  02 ++0 000 02 0 000 025 + 0,000 010 5 (14)
CC
where
u(V ) is the standard uncertainty associated with the volume of copper(II) chloride solution used
C
in the calibrator solutions;
V is the volume of copper(II) chloride solution used in the calibrator solutions.
C
−2
EXAMPLE 2 When V is 500 ml, then u(V ) is 1,959 × 10 ml with 98 degrees of freedom. This is based on an
C C
estimate of 30 degrees of freedom for each of the four contributing uncertainties in Formula (14) and applying
the Welch-Satterthwaite formula in Clause 11.
From Formulae (13) and (14) it can be s
...