SIST EN ISO 13565-3:2002

SLOVENSKI STANDARD
SIST EN ISO 13565-3:2002
01-januar-2002
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Geometrical Product Specifications (GPS) - Surface texture: Profile method; surfaces
having stratified functional properties - Part 3: Height characterization using the material
probability curve (ISO 13565-3:1998)
Geometrische Produktspezifikation (GPS) - Oberflächenbeschaffenheit:
Tastschnittverfahren; Oberflächen mit plateauartigen funktionsrelevanten Eigenschaften
- Teil 3: Beschreibung der Höhe von Oberflächen mit der Wahrscheinlichkeitsdichtekurve
(ISO 13565-3:1998)
Spécification géométrique des produits (GPS) - Etat de surface: Méthode du profil;
surfaces ayant des propriétés fonctionnelles différentes suivant les niveaux - Partie 3:
Caractérisation des hauteurs par la courbe de probabilité de matiere (ISO 13565-3:1998)
Ta slovenski standard je istoveten z: EN ISO 13565-3:2000
ICS:
17.040.20 Lastnosti površin Properties of surfaces
SIST EN ISO 13565-3:2002 en
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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SIST EN ISO 13565-3:2002

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SIST EN ISO 13565-3:2002

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SIST EN ISO 13565-3:2002

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SIST EN ISO 13565-3:2002
INTERNATIONAL ISO
STANDARD 13565-3
First edition
1998-11-15
Geometrical Product Specifications (GPS) —
Surface texture: Profile method; Surfaces
having stratified functional properties —
Part 3:
Height characterization using the material
probability curve
Spécification géométrique des produits (GPS) — État de surface: Méthode
du profil; surfaces ayant des propriétés fonctionnelles différentes suivant
les niveaux —
Partie 3: Cartactérisation des hauteurs par la courbe de probabilité
de matière
A
Reference number
ISO 13565-3:1998(E)

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SIST EN ISO 13565-3:2002
ISO 13565-3:1998(E)
Contents Page
1 Scope .1
2 Normative references .1
3 Definitions .1
4 Procedure .2
5 Measurement process requirements .3
6 Drawing indications.3
Annex A (normative) Procedures for determining the limits of the linear regions .4
Annex B (informative) Background information .9
Annex C (informative) Determination of UPL and LVL via second derivatives.13
Annex D (informative) Normalization of the bounded material probability curve .16
Annex E (informative) Relation to the GPS matrix model .18
Annex F (informative) Bibliography.20
©  ISO 1998
All rights reserved. Unless otherwise specified, no part of this publication may be reproduced or utilized in any form or by any means, electronic
or mechanical, including photocopying and microfilm, without permission in writing from the publisher.
International Organization for Standardization
Case postale 56 • CH-1211 Genève 20 • Switzerland
Internet iso@iso.ch
Printed in Switzerland
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SIST EN ISO 13565-3:2002
© ISO
ISO 13565-3:1998(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.
Draft International Standards adopted by the technical committees are circulated to the member bodies for voting.
Publication as an International Standard requires approval by at least 75 % of the member bodies casting a vote.
International Standard ISO 13565-3 was prepared by Technical Committee ISO/TC 213, Dimensional and
geometrical product specifications and verification.
ISO 13565 consists of the following parts under the general title Geometrical product specifications (GPS) —
Surface texture: Profile method; Surfaces having stratified functional properties:
 Part 1: Filtering and general measurement conditions
 Part 2: Height characterization using the linear material ratio curve
 Part 3: Height characterization using the material probability curve
Annex A forms an integral part of this part of ISO 13565. Annexes B to F are for information only.
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SIST EN ISO 13565-3:2002
©
ISO
ISO 13565-3:1998(E)
Introduction
This part of ISO 13565 is a geometrical product specification (GPS) standard and is to be regarded as a general
GPS standard (see ISO/TR 14638). It influences the chain link 2 of the chains of standards on roughness profile
and primary profile.
For more detailed information on the relation of this standard to the GPS matrix model see annex E.
This part of ISO 13565 provides a numerical characterization of surfaces consisting of two vertical random
components, namely, a relatively coarse "valley" texture and a finer "plateau" texture. This type of surface is used
for lubricated, sliding contact, for example in cylinder liners and fuel injectors. The calculations necessary to
determine the parameters Rpq, Rvq, and Rmq (Ppq, Pvq, and Pmq) used to characterize these two components
separately involves the generation of the material probability curve, the determination of its linear regions, and the
linear regressions through these regions.
The parameters are undefined for surfaces not consisting of two such components.
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SIST EN ISO 13565-3:2002
INTERNATIONAL STANDARD  © ISO ISO 13565-3:1998(E)
Geometrical Product Specifications (GPS) — Surface texture:
Profile method; Surfaces having stratified functional properties —
Part 3:
Height characterization using the material probability curve
1 Scope
This part of ISO 13565 establishes the evaluation process for determining parameters from the linear regions of the
material probability curve, which is the Gaussian representation of the material ratio curve. The parameters are
intended to aid in assessing tribological behaviour, for example of lubricated, sliding surfaces, and to control the
manufacturing process.
2 Normative references
The following standards contain provisions which, through reference in this text, constitute provisions of this part of
ISO 13565. At the time of publication, the editions indicated were valid. All Standards are subject to revision, and
parties to agreements based on this part of ISO 13565 are encouraged to investigate the possibility of applying the
most recent editions of the standards indicated below. Members of IEC and ISO maintain registers of currently valid
International Standards.
ISO 1302:1992, Technical drawings — Methods of indicating surface texture.
ISO 3274:1996, Geometrical Product Specifications (GPS) — Surface texture: Profile method — Nominal
characteristics of contact (stylus) instruments.
ISO 4287:1997, Geometrical Product Specifications (GPS) — Surface texture: Profile method — Terms, definitions
and surface texture parameters.
ISO 13565-1:1996, Geometrical Product Specifications (GPS) — Surface texture: Profile method; Surfaces having
stratified functional properties — Part 1: Filtering and general measurement conditions.
ISO 13565-2:1996, Geometrical Product Specifications (GPS) — Surface Texture: Profile method; Surfaces having
stratified functional properties — Part 2: Height characterization using the linear material ratio curve.
3 Definitions
For the purposes of this part of ISO 13565, the definitions given in ISO 3274, ISO 4287, ISO 13565-2 and the
following apply.
3.1
material probability curve
a representation of the material ratio curve in which the profile material length ratio is expressed as Gaussian
probability in standard deviation values, plotted linearly on the horizontal axis
NOTE — This scale is expressed linearly in standard deviations according to the Gaussian distribution. In this scale the
material ratio curve of a Gaussian distribution becomes a straight line. For stratified surfaces composed of two Gaussian
distributions, the material probability curve will exhibit two linear regions (see 1 and 2 in figure 1).
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SIST EN ISO 13565-3:2002
© ISO
ISO 13565-3:1998(E)
Key
1 Plateau region
2 Valley region
3 Debris or outlying peaks in the data (profile)
4 Deep scratches or outlying valleys in the data (profile)
5 Unstable region (curvature) introduced at the plateau to valley transition point based on the combination of two distributions
Figure 1 — Material probability curve
3.2
Rpq (Ppq) parameter
slope of a linear regression performed through the plateau region
See figure 2.
NOTE — Rpq (Ppq) can thus be interpreted as the Rq (Pq)-value (in micrometres) of the random process that generated the
plateau component of the profile.
3.3
Rvq (Pvq) parameter
slope of a linear regression performed through the valley region
See figure 2.
NOTE — Rvq (Pvq) can thus be interpreted as the Rq (Pq)-value (in micrometres) of the random process that generated the
valley component of the profile.
3.4
( )
Rmq Pmq parameter
relative material ratio at the plateau to valley intersection
See figure 2.
4 Procedure
The roughness profile used for determining the parameters Rpq, Rvq and Rmq shall be calculated in accordance with
ISO 13565-1. This roughness profile is different from that in ISO 4287. The profile for determining the parameters
Ppq, Pvq and Pmq shall be the primary profile.
Three non-linear effects can be present in the material probability curve as shown in figure 1 for measured surface
data from a two-process surface. These effects shall be eliminated by limiting the fitted portions of the material
probability curve, using only the statistically sound, Gaussian portions of the material probability curve excluding a
number of influences.
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SIST EN ISO 13565-3:2002
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ISO 13565-3:1998(E)
In figure 1 the non-linear effects originate from:
 debris or outlying peaks in the data (profile) (labelled 3);
 deep scratches or outlying valleys in the data (profile) (labelled 4); and
 unstable region (curvature) introduced at the plateau to valley transition point based on the combination of two
distributions (labelled 5).
These exclusions are intended keep the parameters more stable for repeated measurements of a given surface.
Figure 2 shows a profile with its corresponding material probability curve and its plateau and valley regions and the
parts of the surface that defines the two regions. The profile has a peak that is outlying and the figure shows how it
does not influence the parameters. Figure 2 also shows how the bottom parts of the deepest groves, which will vary
significantly depending on where the measurements are made on a surface, are disregarded when determining the
parameters.
Figure 2 — Roughness profile with its corresponding material probability curve and the regions used
in the definitions of the parameters Rpq, Rvq, and Rmq
5 Measurement process requirements
The following criteria are designed to ensure that the profile represents a proper two-process surface and that the
measuring process is adequate for calculating a stable material probability curve resulting in reliable parameter
values. These criteria shall be met in order for the parameters Rpq, Rvq, and Rmq (Ppq, Pvq, and Pmq) to be defined:
 The instrument shall be capable of measuring a value of Rq from an optical flat that is less than 30 % of the
nominal value of Rpq (Ppq).
 The vertical resolution of the material probability curve shall be such that at least 40 classes fall within the linear
plateau and linear valley regions respectively.
 The digital data density of the material probability curve shall be such that at least 100 profile ordinates fall
within the linear plateau and linear valley regions respectively.
 The ratio Rvq: Rpq (Pvq: Ppq) shall be at least 5.
 The conic section regressions result in a hyperbolic solution (see annex A).
If the profile does not satisfy the above criteria, a suitable warning message shall give the reason for the failure.
6 Drawing indications
The parameters specified in this part of ISO 13565 shall be indicated on drawings in accordance with ISO 1302.
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SIST EN ISO 13565-3:2002
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ISO 13565-3:1998(E)
Annex A
(normative)
Procedures for determining the limits of the linear regions
Clauses A.1 through A.3 specify the procedures for determining the upper plateau limit, UPL, and the lower valley
limit, LVL. Clauses A.4 through A.6 specify the procedures for determining the lower plateau limit, LPL, and the
upper valley limit, UVL . Clause A.7 specifies the procedure for determining the calculation of parameters.
A.1  Initial conic fit
A conic section is initially fitted through the material probability curve since it is a very good approximation of the
expected form of the material probability curve of surfaces consisting of two vertical random components. This initial
conic fit provides a framework for subsequent operations on the material probability curve.
Fit a conic section
2 2
z = Ax + Bxz + Cz + Dx + E
where
z is the profile height;
x is the material probability expressed in standard deviations;
through the entire curve (see figure A.1).
Figure A.1 — Conic section based on the entire material probability curve
A.2  Estimation of plateau to valley transition
Determine the asymptotes of the conic section (lines designated "a" in figure A.1). Bisect the asymptotes with a line
(line designated "b" in figure A.1). The intersection of this line with the conic section serves as an initial estimate of
the plateau to valley transition (see A in figure A.2).
NOTE — Graphically the bisector line may appear to be at a improper angle (see figure A.1). This is because of the different
scaling of the two axis on figure A.1. See also clause A.4 and annex D for the normalized material probability curve, where the
bisector line appears consistent.
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SIST EN ISO 13565-3:2002
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A.3  Determination of UPL and LVL
The second derivative is computed at each point of the material probability curve starting at the transition point "c"
and working upward through the plateau region and downward through the valley region.
The second derivative at each point is computed using a "window" of 0,05 standard deviations (– 0,025 × s around
the point at which the derivative is to be recorded). See B in figure A.2.
NOTE — The number of points within the window will vary as it is passed through the curve.
For the valley region and the plateau region individually:
 find 25 % of the number of points to one side of the point "c"; call this value i;
 working out from point "c", the standard deviation, s , is computed for the second derivative values using
i
i
points on one side;
 the value of the second derivative at the next point (D ) is divided by the standard deviation, s :
i + 1 i
D
i+1
T =
s
i
 if T < 6, increment i by 1, recompute s and T;
i
 if T > 6, data point i is the limit of that region (UPL for the plateau region and LVL for the valley region,
respectively). See also C in figure A.2.
Figure A.2 — Bisection of the asymptotes is the initial transition point between the two regions
of the material probability curve and the corresponding second derivatives
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SIST EN ISO 13565-3:2002
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ISO 13565-3:1998(E)
A.4  Normalization of the bounded region
The Z-axis of the material probability curve is normalized such that the bounded region (region between UPL and
LVL) is "square" (see annex D). This insures consistent bisection of the conic section asymptotes (see figure A.3).
A.5  Second conic section fit
The conic section is now regressed through the region within UPL and LVL. The asymptotes are constructed (see
figure A.3).
NOTE — For k , see annex D.
s
Figure A.3 — Conic section determined within the upper plateau limit, UPL, and the lower valley limit,
LVL — Normalized material probability curve
A.6  Determination of LPL and UVL
To determine the lower plateau limit, LPL , and the upper valley limit, UVL , the asymptotes are bisected three times
(b: first time; P2 and V2: second time; P3 and V3: third time). The intersection of thes
...