SOIL MOISTURE PROFICIENCY SAMPLE PROGRAM SHA 730 X SHRP P 619

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SHRP-P-619
Soil Moisture Proficiency
Sample Program
Garland W. Steel, P.E.
Steel Engineering, Inc.
Strategic Highway Research Program
NationalResearch Council
Washington,DC 1993
PUBL. NO. SHRP-P--619
Program Manager: Neil Hawks
Production Editor: Marsha Barrett
Program Area Secretary: Cindy Baker
February 1993
key words:
base course aggregates
cohesive soils
Strategic Highway Research Program
National Academy of Sciences
2101 Constitution Avenue N.W.
Washington, DC 20418
(202) 334-3774
The publication of this report does not necessarily indicate approval or endorsement of the findings,
opinions, conclusions, or recommendations either inferred or specifically expressed herein by the National
Academy of Sciences, the United States Government, or the American Association of State Highway and
Transportation Officials or its member states.
© 1993 National Academy of Sciences
350/NAP/293
Acknowledgments
The research described herein was supported by the Strategic Highway Research
Program (SHRP). SHRP is a unit of the National Research Council that was authorized
by section 128 of the Surface Transportation and Uniform Relocation Assistance Act of
1987.
°°°
m
Contents
Acknowledgments .................................................. iii
Abstract ........................................................... vii
Summary of Research ................................................ 1
Appendix I--Descriptive test results on materials used by AMRL for samples ....... 5
Appendix II--AMRL report on SHRP Moisture Content Proficiency Sample Program 13
Appendix III---Correspondence regarding transmitting AMRL report ............ 103
Appendix IV--Correspondence concerning analysis of data ................... 107
Appendix V--Memorandum on variance component analysis .................. 113
Appendix VI--Example of report distributed to each participant ............... 135
Appendix VII--AASHTO/ASTM format precision statements ................. 143
V
Abstract
This report describes the developmentofthe Long-Term Pavement Performance (LTPP)
soil sample selection process based on the American Association of State Highway
Transportation Officials (AASHTO) model. Lab results present the bias in determining
moisture content in cohesive soil and base course aggregate samples.
vii
SUMMARY OF RESEARCH
FINAL RESEARCH REPORT
on the
SHRP SOIL MOISTURE PROFICIENCY SAMPLE PROGRAM
One element of QualityAssurance (QA) for laboratory testing that
was deemed to be of key importance by SHI_P, as a resultof Expert
Task Group (ETG) recommendations, is the American Association of
State Highway and Transportation Officials (AASHTO) accreditation
program (AAP) for laboratories. All laboratories providinglong
term pavementperformance (LTPP) testingservices were required
to beaccredited by AAP. Most ofthe laboratorytests on LTPP
fieldsamples were addressed by the AAP, which includes onsite
inspections of equipment and procedures,and participation in
applicable proficiency sample series. However, a few critical
tests in the SHRP LTPP studies were not fully addressed. After
extensive consultation and careful study,it was determined that
supplemental programs should be designed to provide assurance of
quality testdata in a manner similar to that provided by AAP for
other tests.
The Soil Moisture Proficiency Sample Program was one of the
supplemental programs approved for implementation. The program
was designed to provide precision and bias data concerning
standard tests for moisture content of subgrade soils and base
course aggregates.
The soil moisture program was modeled after the familiar AASHTO
Materials Reference Laboratory (AMRL) proficiency sample
programs at the National Institute of Standards and Technology
(NIST). The moisture samples were prepared and distributed to
participants, the raw test data was collected and collated, and a
report documentingthe program was issued for SHRP by the AMRL.
Two different cohesive soils were supplied for the program by the
Maryland Department of Transportation's Materials Laboratory.
These soils were from the same sources that were used in the Type
II Soil Proficiency Sample Program. Soil classification data is
contained in appendix I.
Two different base course aggregates were supplied for the
program by the University of Nevada-Reno. The aggregates were
from the same sources that were used in the Type I Proficiency
Sample Program. It is also noted that these materials were
obtained from SHRP reference material sources,Watsonville
Granite at Monterey, California and Kaiser at Pleasonton,
California. Classification data for the materials used is
contained in appendix I.
AMRL thoroughly blended, then split each of the four primary
materials into two approximately equal parts,one part to
3
eventually provide material for dry samples and the other part to
eventually provide material for wet samples. Each of these 8
parts was then split again into two approximately equal portions
designated as split A and split B. Each of the 16 splits(8 A and
8 B) was then split to yield 64 test samples. 8 of the sets of
64 samples were finally processed for distribution in an air
dried condition and the other 8 sets were processed for
distribution in awet condition.Finally, 20groups of3test
samples each were randomly selected from each of the 16 sets of
64 test samples and identified for shipment to each participating
laboratory. Every participant received a total of 48 test
samples (16 groups of 3test samples each).
All samples were selected and identified in accordance with
statistically acceptable random procedures. The entire
experiment was designed in consultation with SHRP statisticians
to allow a completecomponents of variance analysis to be
conducted as resources allowed.
Instructions to the participants (appendix II,page 7) provided
directions concerningtest sequencing,identification and
procedure to follow (AASHTO T265).
Raw test data was returned to AMRL for collation and
incorporation into the AMRL report(appendix If). The report was
forwarded to the SHRP Quality Assurance Engineer when all data
had been received. It was then transmitted to the SHRP
Statistician for analysis and determination of test precision and
bias.
The Statistician's report (appendixV) provides a full
explanation of the data analysis alongwith complete information
derived therefrom.
Precision statements (appendix VII) were drafted in the standard
AASHTO\ASTM format for use by standards writingcommittees as
they deem appropriate.
The appendices to this report contain the complete set of
supportingdocuments for this program as listed in the table of
contents.
Seventeen (17) laboratories participated in this experiment.
Each participant has made a substantial contribution to the
successful completion of SHRP research in the LTPP program.
The participants are listed in Appendix II, page 11.
4
APPENDIX I
SHA-73 0-32
\REVISED 3-75 MATERIALSAND RESEARCH
LaboratoryWorksheet
COMBINED HYDROMETER, SIEVE ANALYSIS AND TEST DATA SHEET
Z
o_ LOG NO.= /../(2. 728c'f CONTRACT=/40- 2(72 - ZO7- "7"7fFIELD CLASS: .a,__ _ ,/?.f.
c, LOCATION - STA. (_7_ _ So /5o '/TT. I# g'_/_( DEPTH:. O,& '7o
E_.
EST. MOIST.: /4 OPT. MOIST.DATE: 6-5- 9o CUT _ FILL rl NC/NF []
OPERATOR _.-7_ DATE G,-?o-90CHECKED BY _, _ DATE /;/7e/'_-
CLASSIFICATION : MSMT/_.(t'.7 ")('- AASHO/_ .C ¢_ _ EST. C.B.R. VALUE
LIQUID LIMIT D: 3"-- SHRINKAGE LIMIT: /_ SHRINKAGE'} 95%T-180
PLASTICITY INDEX: //. SHRINKAGE RATIO: /,"7_ r-I FACTOR j" 98% T- 99
MOISTURE DENSITY_[_-180 C MAX.DEN.= pcfOPT. MOIST.=%
RELATIONS Jr'IT-99 MAX. DEN. = pcf OPT. MOIST. = %
GRADATION (PERCENT PASSING by WEIGHT)PERCENT OFSOIL MORTAR
2_'. _z" _'? #40 "7/ *COARSE SAND:(2.0- 0.42ram) /_ l _G
<_2" 3/o" ,_60(p3 _FINESAND: (0.42- O.075mm) Z-_ J
r_ lY_"_4_ =riO0 --%-_ SILT=(0.075-0.005mm)
I" //00 _I 0 8_/==200 ¢/'7 "CLAY =(0.005 -0.001 ram) _ __/
34- 9"?#30 #270 COLLOIDS,(O.OOImm Minus) J_
MOISTURE AT ( )=%( ); MOISTURE AT ( )=%( )
I-I ORGANIC TEST=%, [] P.H. , [] OTHER TESTS._-_t_ _ _.-(.- 7
[] COLOR rl C.B.R. %, ( ),r-i VOL. CHANGE %
REMARKS;_- "f-_. ,,'_/_ ._olc S'[,_/L / 7/7/o/_[ ,_77-h'.I._ k.'cC_:_
I]_24 Hr.Bath [] MSMT El=_40Wash El _200 Wash [] No Bath Required
MECHANICAL ANALYSIS DATA
o'(Wo) 23./2-TEST SAMPLE
(We)- ?__i__ .... W=x I00 +(% HYGRO =Ws
"" (W,)2_, xlOO+Ws = _'-I% HYGROWo= 3-,3_. /? W== _,.._
SEDIMENTATION TEMP I I(R/Ws)XlO0 EST.MAX.
_RA_ 'COARSE SAND
__ STA.T Jw,NOF HCT R[%CLAY"SlZEmm P_,I0 - P_40 =/_
<_
m CFINE SAND_
/..oo_ Pp40 - Pp200=
FINE SIEVE ANALYSIS NOMENCLATURE
WHERE, Pp=Wp X I00 Pp I0=100 MAX.
Ws _AIN WHERE :
u)IS_ZE
% TOTAL mm
__ SIEVE w,= ._j.<_'P_ ;: s/'oo%A,_L(_ASS Wo=Air Dry (gin)
t--W, = Oven Dry (gm)
_-50 w, -- 0.60 W,'= WaterWt. (gin)
w_= ¢H = HydrometerReading
J " C = Tamp.Correction Factor
<_: -#'40w_ -- _ _./
(J w_'_= _.7_ _'_ 03 _:_7_ ._7 7/0.425 R=Corrected Hydrom. Reading
PR= % Setup.Retained onSieve
#60 w,-- 3"-_Pp=%Sample Passing Sieve
w,= 37._-<" "7/._ (_ * 7Z _'_' ('_ o.2_o
- W== Wt. RetainedonSieve (gin)
-#'lO0 w,-- _ ._,/S ='%Total Sample Passing
w,= 3_'.'/?--(..1. D..{:I:G_ . g7 550.150 # I0 Sieve
w, -- _.D_ W_= Wt Possing Sieve (gm)
#z_o ,,= 2?._3_<3_73:_54 ._7 =..7 o.o7_
w,-- 0.053
7
LOG.NO. /JO • lze,-?24 HOUR HYDROMETER ANALYSIS
Re
P=-_s X I00 d =dI=K,xKGx K.
WHERE ; WHERE :
'_P= % Soil in Suspension d = Corrected GrainDiameter
..J
:D R=Corrected Hydrometer Readingd, = Max.Groin Die. UnderAssumedConditions
rr a =Constant -Depending on Specific Gravity KL=Correction for Elevation of Hydrometer (H)
OWs=OvenDry Weight of Test Sample KG= Correction for Variationof Specific Grovity
H = Hydrometer Reading, Uncorrected. K.= Correction for Variation ofViscosityof
C = Correction Factor for Temperature Suspending Medium.
S= % Total Sample Passing#10Sieve
S, = % Totol Somple Passing
o = (_._ Ws= 5_..E_ %Total Sample Passing #10(S} _7 Sp. Gr. 7.. _7
OBS. T
TEMPoF ( H + C = R ) IOOo = Px S/IO0= S, i KL x KG K.
! Ws TIME MIN.d, =
1
I-30 .o811
_L_ _/.._ _- 21 I .057o4o
o ._ z z(,-.3 /_z3 q7.ct_'?,... @_ . o_ i .o3_.
5 .o26 ._'_'c ,o,.q"7.'1.o:j
<7.;- 3_'.o-5._- zq._, yEz-37
..J
:D
(D
.Ji
<o 7;27.5-S.'__2.¢ . ,_.3 3_"_5 .or5 i.e___ .0¢4# 1.0/?.-:
I
60 .0074 I " O'_.obT/ ',.o_C-2I
_I" Zl . O i_ i ;i i
_<._ l)_-.u z_.P -_,/ 250 1.0036 .8-_.'.o_3.EI.oo3/]
!- ' I !
7¢¢e_ i-_.(-[/_.'/I.'_=3i;,=.*_
MECHANICAL ANALYSIS (AASHO DESIGNATIONS M146 AND T.88}
U.S. STANDARDSIEVE SIZE THYDROMETER ]
,oo -_ "_ --_"_ "_ _ _ :_ =_ =_ _" :_ _" to
90 i ' "_ hO
li!I ; , z
BO:-7_.'_..,.2C
"tO , 1 ''' .... ' ' '3C
so' '_,' = ' .,;c,-_
_0 50 5C >-
I!I'i,_ m
_. ,80
I0_- ,' I190 _
I{'_'00
-- _ e_ _r 0 _ o _ o Qvoo o
GRAIN SIZE INMILLIMETERS
COARSEIMEOUMt.,.E COARSEI.,.E SILT
% SOIL MORTAR=READINGFROMCURvE+S/Io0 REMARKS:O.O0--C _--27. d-- ,q.,7-._31
-.,"
,-r'Al._=,_
SHA-730-32
REVISED 3-7_MATERIALSAND RESEARCH
Loborotory Worksheef
COMBINED HYDROMETER, SIEVE ANALYSISANDTEST DATA SHEET
o_ A A-)_r #
LOG NO.: CONTRACT' r"/J// FIELD CLASS:
uLOCATION - STA. DEPTH:
E
EST. MOIST.'OPT. MOIST. DATE'CUT[] FILL [] NC/NF []
__ OPERATOR/..'r _ DATE 3 -I _, -_0CHECKED BY _._=_ DATE ,,_-z/-?o
CLASSIFICATION : MSMT "_ AASHO/,"-_ EST. C.B.R. VALUE /
LIQUID LIMIT [] : _'_/SHRINKAGE LIMIT= _" SHRINKAGE_95%T-180
PLASTICITY INDEX://" SHRINKAGE RATIO: /. /_ i_ r-i FACTOR J" 98% T- 99
MOISTURE DENSITY_Ig_-180 _- MAX. DEN.= _7/._tpcfOPT. MOIST. = 3/.g" %
RELATIONS JnT-g9__ MAX. DEN. =pcfOPT. MOIST. =%
GRADATION (PERCENTPASSING by WEIGHT) _(PERCENT OFSOIL MORTAR
12_:_z" "40 *COARSE SAND ' (2.0-0.42mm) ._ _)_)
_'8"_e60 _ *FINE SAND=(0.42- O.075mm) 7. _ t
1Y="w48100 73_ SILT : (0.075 - O.O05mm ) =/5
I" ,_I 0 /0 L_ =200 (_ _ "CLAY: (0.005 - 0.001 mm)
_-_/,"#30 #270COLLOIDS_(O.OOImmMinus)
MOISTURE AT__ ( )=__.%(); MOISTURE AT__( )=%()
r-I ORGANIC TEST: %, I'1 PH. , I-I OTHER TESTS =_/o _p.Z. 73
[] COLOR rl C.B.R %, ( ),E3 VOL. CHANGE %
REMARKS:
2B_4 Hr. Bath r-; MSMT El _40 Wash r'l +200 Wash [] No Bath Required
MECHANICAL ANALYSIS DATA
9! '(W=)_(=,. 3._ .... TEST SAMPLE
_! CW,)-'" _'_i"'_"_" WaX100 lHYGRO+I00)= W,
= (W,) .'7#xlOO ¨DhZ?% HYGRO Wo= .._'.E._Z/W== _.3-_"
_[ SEDIMENTATION [TEMP H-I C IR (R/Ws)XIO0 EST'"AX"
o.*'. "COARSE SAND
START llllN.°F T % CLAY" S/ZmE Pp IO- Pp 40= -/
i/.oo5P,40 -P,200=
FINE SIEVE ANALYSIS NOMENCLATURE
WHERE' P_= _ X I00 PpI0=100 MAX.
=_A,, WHERE :
SIZE
""
(nSIEVE *,";PP ::s/Ioo .s_u.pt.=pAs_ Wo = Air Dry(cjm)
W, = Oven Dry (gin)
<w, -- W, "= Water Wt. (gin)
.J _30 0.60
:3 wp=H=HydrometerReading
o¢
..J C =Tamp• Correction Factor
<#4o *--'- Lt,'tC,
iwp" L(? _ _ I /_:1: _/ /.0 _/0425R : Corrected Hydrom. Reading- - P_ = % S_mp.Retained on Sieve
*._ -- _ .3/P_= % SamplePassing SieveW= = Wt. Retained onSieve (gin)
#_oo ,,-- _ __0S=% Total Sample Passing
'_"_o z_,"T_ e)O :_ 7_f.o 7So.,50 _elO Sieve
" " Wp = WtP_ssin9 Sieve(gin)
#200 ._ -- (. ?//
'_"3_ .'_7_. _-_ , (.o7.- f.G G_"oo7s
-_270 w, -- 0.053
LOG.NO. /_rT._ .-F _24 HOUR HYDROMETER ANALYSIS
Ro
P = _XlO0 d = dlxKLxK_x K.
WHERE :WHERE:
<1 P =% Soil in Suspension d = Corrected Groin Diameter
R=Corrected Hydrometer Reading d, =Max. Grain Did.UnderAssumedConditions
a=Constant -DePendingon Specific Gravity KL= Correction for Elevation ofHydrometer (H)
_i W== Oven Dry Weight of Test Sample Ks.-- Correction for Variation of Specific Gravity
"1H=Hydrometer Reading,Uncorrected. K. =Correction for Variation of Viscosity of
C=Correction Factor for Temperature Suspending Medium.
S= % Total Sample Passing#10 Sieve
S, = % Total Sample Passing
i
a = O. _ W_= _3._:_C"%Total Sample Passing#10(S)/dO Sp. Gr. 2..'/.-_
[ ! j j I MIN.I I ) I
TEMP. (H + C = R) x IOOo =pxS_IO0=S, OBS. T d, x KLx K_K. =d
-tTIME i t
°FIW,I r
'I'I
3o_. .osiI,I I
/ I ii- , .027 I I
7.'7;_.o-_,._-.o26i._z_t .o_7 !.o_-_
;[I- ''
.I,!I
I i-'I
-_?.l_';.oI-".:,'_';I ,,7._!rr Go .oo74,._i._==?oo_.II
oI
! ' ' i
_o Io.oi/o.dlozso .oo_6!.15o .do33
II
' i _ i
I'i
MECHANICAL ANALYSIS(AASHO DESIGNATIONS M.146 AND T.88]
U.SSTANDARD SIEVE SIZE IHYDROMETER1
l
I00 0
ll!t!I I I; t !I: _ Iii I_ _1 I _"----_!1111:1Ii _ I ;!:1 Ii!!ti! i I! t ! I! , liiii1!i + _,,, _ -
_ _o_:i;_,,__.1_ _4o__"
t I I
;i;i i I ii !!1i'Ii,_I!tl,%. '_
, , ',=;=
= !1!!! !! ! ..t! !1 I I i;_ z.
'°li!!, ii_ _li li 1 J: i[!i___i =
!iliIi: .i i _', ,, _IIII III I -_,oc
,,,_ _ o _ _ o
!o
-_GRAIN SIZE INMILLIMETERS
GI_AVEL_AN[) II1COARSE MEDIUM tFINE COARSE 1FINE SILT CLAY
%SOIL MORTAR-READINGFROMCURVE+_o0 REMARKS: O.OID_ _ /(_.8 _', I.(_ _1, t'7
10
SHRPPROFICIENCY SAMPLES
FOR RESILIENT MODULUS TESTING
OF UNBOUNDED MATERIAL
(Gradation)
__ii!ii iiiiii:i_iiiii:iiii:iiii]iililii!_i:i_!iiiiii_i_:ii!iiiii!iii!!iiii_:ii i!iii!ii!iiiiil!!_ _:
:::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::
1.5" 100
r' 82
3/4" 73
1/2" 61
3/8" 52
#4 39
#8 27
#16 21
#30 15
#50 10
#100 8
#200 6
AASHTO Soil Classification Unified Soil Classification
A-l-a GW-GM
PLASTIC INDEX
np
Material Identification Specific Gravityof Specific Gravity of
Material Passing #4 Material Retained on #4
WatsonviUe 2.777 2.865
Pleasonton 2.713 2.748
11
APPENDIX II
13
SHRPMoisture Content
Proficiency Sample
Program
1S
S.H.1LP. Moisture - Content Proficiency Sample Program
CONTENTS
Correspondence Document
The correspondance document that wasmailedto the 17 laboratories participating
in the S.H.R.P. Moisture Content Proficiency SampleProgram, consists of an
Instruction page, a copy of the Standard Test method, and a Data sheet to be used
for recording testresults.
* Although only 17 complete samples weredistributed by AMRL, (17 laboratories
participated in the Proficiency Sample Program) 20 completesamples were
prepared, leaving 3 complete samples toserve as replacements in case of loss or
damage during shipment. As a result, the following report reflects the in-house
data recorded for 20 complete samples. (A complete sample is defined as 16 Sets
of 3 sub-samples each, with oneSet coming from eachof the 16 Sample Types).
Section 1 - Master Identification Record
Laboratory Identification Sheet
This sheet identifies each laboratory participating in the program. Each
laboratory was assigned a number which is used to identify and trace the
laboratories data.
TestSample Splitting Procedure
Thisdocument illustrates the process used to split the material fromthe Split
A or Split B portion to yield 64sub-samples. Each ofthe 4 Primary materials was
blended and then splitinto 2 approximately equal portions. Each of these
portions was then split to yield 2 portions,onehalfbeingidentified as Split
A, and the otherhalf being identified asSplit B. Each ofthe splits,(SplitA
or Split B) was then split toyield 64sub-samples. Each laboratorywas shipped
3 randomly selectedsub-samplesfromthe 64sub-samples. (3 sub-samples
constitute one Setfor a particular material type.
Sample TTpe Identification Sheet
This document describes the attributes of each of the 16 different sample types.
It also identifies the four primary materials that were used to in preparing the
samples. Eachlaboratory was shipped one set, (3sub-samples) from each of the
16 Sample Types.
Each Sample Type is described by the following criteria:
* Primary material type. (Aggregate 1 or Aggegate 2, Soil 1 or Soil 2)
* Which half of the split the sample originated from. (Split A or Split B)
* Moisture condition of the material. (Air dry, Plastic Limit or Saturated
Surface Dry.
17
Toapproximate the plasticlimitorsaturatedsurface dry condition, the
following moisture contents were added to the air dry samples:
*Aggregate 1 --> 2.00 ! .04% moisture.
* Aggregate 2 --> 3.00 _ .04% moisture.
* Soil 1 --> 15.00 ± .04% moisture.
* Soil 2 --> 25.00 ± .04% moisture.
Laborator7 Sub-Sample Identification Sheet
These sheets identify the 3randomly selectedsub-samples that were assigned to
each laboratory for a particular sample type. The sub-samples thateach
laboratory received are identified bysample type number and the letter a, b or
c on the data sheets. The sheets also identify the proper set testingsequence
for that set of 3 sub-samples. The numbers were assigned usingthe Lotus random
number generator function.
Example: For Sample Type No. I, Laboratory No. 1 was assigned sub-sample No.'s
12, 42 and 57. These 3 sub-samples are identified as Sample#'s la, ib and Ic
respectively. These 3 sub-samples were labeled Set #II,meaningthat from the
total group of 16 sets received by the laboratory, Sample Type No. 1 would be
the eleventh set tested.
Laboratory Set Testln K Sequence Table
This table shows the Set TestingSequence for all of the laboratories. There is
acolumn for each sample type and arow for each laboratory.
Section 2 - Master Data Record
Master Data Record
These are the data tables used to record the mass and the amount of moisture
added to the sub-samples prepared by AMRL. These data sheets may be compared with
the Returned DataSheets shown in Section3.
Section 3 - Returned Data Sheets
Returned Data Sheets
These datasheets were filled out by participating laboratories and returned to
AMRL.
Returned Tare Weights
*Note that Laboratory No. 's3, 7, 9, 10, Ii, 13 and 19 did not comply with the
request to record the tare weights of the bags on the back of the DataSheet.
* When comparingthe respective masses of the sub-samples on the Master Data
Shee_s with the masses of the sub-samples submitted from the laboratories on
the Returned Data Sheets, it appears that some of the laboratories may nothave
used the entire sub-sample when testingfor moisture content.
18
Errors in processing
Notei:Laboratory No. 15 receivedtwo sets identified as Set _I.The Set
containing Sub-Samples 9a, 9b and 9c was inadvertantly identifiedasSet #I when
it should havebeen Set #3.The situation was explained to the laboratory prior
to testing and is considered resolved.
Note 2: Laboratory No. II, Set 8,Sample 9b hadanexcessive amount of moisture
added to the sample. This error is reflected in the laboratories returned data
sheet.
Gregory V.Uherek, AMRL Research Associate
October, 1990
19
Correspondence Document
21
Date
Name of laboratory manager
Laboratoryname and address
Subject: SHRPMoisture ContentProficiency TestSamples
Dear (insert name):
SHEPhas engaged theAASHTO Materials ReferenceLaboratory to prepareand distribute
proficiency test samples for moisturecontentdetermination. In connection withthis effort,
we are sending two boxescontaining16 setsofmaterial to your laboratory.Each set of
material isidentified with a Set Number from 1 to 16 and contains three double-bagged test
samplesidentified with a Sample Number. The twoboxes you receiveshould contain forty-
eighttestsamples (16 sets containing3 samples each).
Please determine the moisture content of each sample in accordance with Section 5 of AASHTO
T265-86. A copy ofthis standard is attached for your convenience. Test each set
individually and in numerical order according to theSet Number(i.e. Begin testingwith Set
Number 1 and end testingwith SetNumber 16.). Donotopen the bags containingatest sample
until the testsample is ready to be tested. Opening the sample bags too soonmayaffect the
moisture contentof the samples.
Please use the enclosed data sheet to record your testresults. (Additional copiesof this
letter, test method T265 and the data sheethave been included in each boxofmaterialbeing
sent to your laboratory.)Set and Sample Numbers have been entered in the appropriate
columns on the data sheetand are exclusive to your laboratory. Record all weightstothe
nearest0.I gand calculate and report the moisturecontent to thenearest 0.01%. After
testingrecord the weight ofthe bagcontainingeach sample and the applicable Setand Sample
Number onthe back ofthedata sheet.
Please testall samples assoon as possible, butnolater than thirtydaysafter receipt, and
return a completed data sheet: GregoryUherek, AASHTO MaterialsReferenceLaboratory,
Building226, RoomA365,Gaithersburg, Maryland 20899.
Ifyou have anyquestions, orifthesamples received are damaged or incomplete,please
contactGreg Uherek at (301)975-6704.
Sincerely,
Peter A.Spellerberg, Assistant Manager
AASHTOMaterials Reference Laboratory
Enclosures
23
d
Z_"
e-
z_- ._o _ tiff fl _ _
0
25
Section 1
Master Identification Record
27
S.H.R.P.MOISTURE CONTENT PROFICIENCY SAMPLE PROGRAM
ParticipatingLaboratories
Braun Engineering Testing, Inc.
Minneapolis, Minnesota55435
CaliforniaDepartmentof Transportation
Sacramento, California 95819
Federal Highway Administration
Denver,Colorado80225
Florida Departmentof Transportation
Gainesville, Florida 32602
Iowa Departmentof Transportation
Ames,Iowa50010
Kansas Department of Transportation
Topeka, Kansas 66611
Law Engineering
Atlanta, Georgia 30324
MarylandState Highway Administration
Brooklandville, Maryland 21022
Minnesota Department of Transportation
Maplewood,Minnesota55109
Nevada Departmentof Transportation
Carson City, Nevada 89712
Oregon State Highway Division
Salem, Oregon 97310
PSI
Pittsburgh, Pennsylvania 15220
Southwestern Laboratories
Houston, Texas 77249
Texas State Departmentof Highways and
Public Transportation
Austin, Texas 78731-6033
University of Nevada-Reno
Reno, Nevada 89557-0030
WestVirginia Departmentof Transportation
Charleston, WestVirginia 25311
Western Technologies Inc.
Phoenix, Arizona 85036
29
i-:,
/%
I.T.i
r-i,
r--:,
r,#,}
°-_
-- !{l,,
" r--i,
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i.i _ _f.LI
i.l.I
r..T.l,,_
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_ _r-
0
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30
S.H.R.P. Moisture Content Proficiency Sample Program
Sample Type Identification Sheet
SAMPLE TYPE NO. SAMPLE DESCRIPTrlON
1........................................... Aggregate 1, Split A, SSD Condition
2........................................... Aggregate 1, Split B, SSD Condition
3........................................... Aggregate 2, Split A, SSD Condition
4........................................... Aggregate 2, Split B, SSD Condition
5........................................... Aggregate 1, Split A, Air Dry Condition
6........................................... Aggregate 1, Split B, Air Dry Condition
7........................................... Aggregate 2, Split A, Air Dry Condition
8........................................... Aggregate 2, Split B, Air Dry Condition
9........................................... Soil 1, Split A, Plastic Limit Condition
10.......................................... Soil 1, Split B, Plastic Limit Condition
11.......................................... Soil 2, Split A, Plastic Limit Condition
12.......................................... Soil 2, Split B, Plastic Limit Condition
13.......................................... Soil 1, Split A, Air Dry Condition
14.......................................... Soft 1, Split B, Air Dry Condition
15.......................................... Soil 2, Split A, Air Dry Condition
16.......................................... Soil 2, Split B, Air Dry Condition
PRIMARY
MATERIALS USED
Aggregate1 - Watsonville, Supplied by University ofReno, Nevada
Aggregate2 - Pleasonton, Supplied by University of Reno, Nevada
Soil 1 - **, Supplied by the Department of Highways, Maryland
Soil 2 - **, Supplied by the Department of Highways, Maryland
31
S.H.R.P. Moisture Content Proficiency Sample Program
Laboratory Sub-Sample Identification Sheet
SAMPLE TYPE NO. 1
Aggregate No. 1, Split A, Saturated - Surface - Dry Condition
_EMAINDERS: 23, 22,40, 63
32
,.. ,_ ,. , '_._i_ _ ,,_'_"_; ,
S.H.ILP. Moisture Content Proficiency Sample Program
LaboratorySub-SampleIdentificationSheet
SAMPLE TYPE NO.2
Aggregate No. 1, Split B, Saturated-Surface - Dry Condition
33
S.H.R.P. Moisture Content Proficiency Sample Program
Laboratory Sub-Sample Identification Sheet
SAMPLE TYPE NO.3
Aggregate No. 2,SplitA, Saturated - Surface - Dry Condition
34
S.H.R.P. Moisture Content Proficiency Sample Program
LaboratorySub-SampleIdentificationSheet
sa_eze nee NO.4
AggregateNo. 2, Split B, Saturated -Surface- Dry Condition
i:!_i:i_:_i:i:_:_:i:i:_:i:i_i:i:i:!_!:i:_:i:i:i:i:_:!:!:!:i:i:_:_:i:_:_j:i:i:i:i:_:i:i:i:i:i:i:i:_:i:i:_:i:i:i:i:_:i:_:i:i:_:_:!:_:i:_:_:i:_:_i:_:!:_:_:i:_:_:_:i:_:i_:_:i_i_i_!_i:i_i_i_i_i:i_i:i:i_i:!_!_i_i_i_:!:i:_3_i:_:_!:_:!:!:_:_:i:_:_:_:_:_:i:_:i:_:i:i:i:i:!:i:i:i:i:!:i:i:i:i:i:i:i:i:!:!_!:i:!:i:j:i:_:_:i`._:_:_:_:i:i:i:i:_:i:i:i:_:!:i:i:i:i:i:i:i_i:i_:i:j:i:i:i:i:i:!:i:!:_:i:i:i:!:!:i:i:_:[:i:_:_:_:_:i:i:_:_:_:_:_:_:i:_:_:i_:i:i:i:_:_:_:_:i:_:_:::::::::::::::::::::::::::::::::::i:i:i:i:i:i:i_i:i:i:i:i_.:.:.:.:.:.:.:.:.:.:._:.:_.:+::.:
_%EMAINDERS : 31,52,5,54
35
S.H.R.P. Moisture Content Proficiency Sample Program
Laboratory Sub-Sample Identification Sheet
SAMPLE TYPE NO.5
AggregateNo.1, SplitA, Air- DryCondition
REMAINDERS:56, 53, 62,50
36
S.H.R.P. Moisture Content Proficiency Sample Program
Laboratory Sub-Sample Identification Sheet
SAMPLE TYPE NO.6
AggregateNo. 1,Split B,Air - Dry Condition
REMAINDERS : 57, 63, 42, I0
37
S.H.R.P. Moisture ContentProficiency Sample Program
Laboratory Sub-Sample Identification Sheet
SAMPLE TYPE NO.7
AggregateNo. 2, Split A,Air - Dry Condition
iiiiiiiiiiiiiiiiii!iiiiiiiiiiiiiiiiiiiii_i_iiiiiiiiiiiiii!iiiiiiiiiiiiiiiiiiiiiiiiiiiiiiii_giiiiiiiii21i!i!!ii!iiiiiiii[iiiiiii_ iii i_ i _ i iilii _ii 1
REMAINDERS : 13, 63, 14,3
38
S.H.R.P. Moisture Content Proficiency Sample Program
Laboratory Sub-Sample Identification Sheet
SAMPLE TYPE NO.8
Aggregate No. 2,SplitB,Air-DryCondition
i:_:i:i:i:_:_:i:!:!:::i:i:i:i:!:_8_:!:!:i:i:!:!:i:i:_:i:!:i:i:i:_:i:i:_:_:i:_:i:i:_:i:i:i:_:_:i:i:i:_:i:i:i:!:i:i:_:i:_:i:i:!:_:::::::::::::::::::::::::_:_:i:£!:i:_:!:_:_:!:i:_:i:i:_:_:_:_:_:_:_:3:i:_:_:!:_:_:_:_:_:i:i:i:i:i:_:i:_:i:i:_:!:_:_:_:!:!:!:_:_:i:_:!:!:i:!:_:i:i:i:_:!:_:_:_:_:_:_:i:i:_:i:33i:_:!
REMAINDERS:54, 30, 63, 46
39
S.H.ILP.Moisture Content Proficiency Sample Program
Laboratory Sub-SampleIdentification Sheet
SAMPLE TYPE NO.9
Soil No. 1, Split A, Plastic- Limit Condition
i:i:i:_:i:i:_:i:i:.:_:i:i:::::::::::::::::::::i::i:J:i:_:!:i:i:_:i:i.i:i:i:_:!:i:!::i:i:i:i:i:i:i:i:i:i:i:!:i:i:i:_:_:_:_:!:i:i:i:::?:i:i:_:i:_:i:i:i:i:i:i:i:_::i:!.i:i:i.i:i:i:i:i:i:i::_:i:i:i:i:i:i:i:_:i.i:_:i:!:i:i:J:i:!:i:i:_:i:i:i:_:_:i:_:_:i:i.3:_:_:i:_:i:_:i:_:_:i:i:i:_:_:i:_',i:!:_:!:!:!_i:i:i:i:i:i:_:_:i:_:i:_:i:_:_:i:_:i:!:_:i:_:i:J:_:i:i:i:i:i:!:_:i:i:i:_:i:i:i:i:i_:_:i:i:i:i:i:i:J:i:_:i:J:_:!:_:i:_;_:_:i:_:_:_:_:i:i:i:::::::::::::::::::::::::::::::::::::::::::_:i:i:_:i:i:i:::i:i:!:i:i:i:i:i:i:i:_:_:!:i:::!:ii:i:::::::::::::::::::::::::::i:i:::
ZEMAINDERS :21, 22, 36,6
4O
S.H.R.P. Moisture Content Proficiency Sample Program
Laboratory Sub-Sample Identification Sheet
SAMPLE TYPE NO.10
Soil No. 1, Split B,Plastic - Limit Condition
_EMAINDERS : 45, 64, 49, 15
41
S.H.R.P. Moisture Content Proficiency Sample Program
Laboratory Sub-Sample Identification Sheet
SAMPLE TYPE NO.I1
Soil No. 2, Split A, Plastic - Limit Condition
42
S.H.R.P. Moisture Content Proficiency Sample Program
Laboratory Sub-Sample Identification Sheet
SAMPLE TYPE NO.12
Soil No. 2, SplitB,Plastic -Limit Condition
REMAINDERS: 26, 2, 47, 37
43
S.H.R.P. Moisture ContentProficiency Sample Program
LaboratorySub-SampleIdentification Sheet
SAMPLE TYPE NO.13
Soil No. 1, SplitA,Air - Dry Condition
44
S.H.R.P. Moisture Content Proficiency Sample Program
Laboratory Sub-SampleIdentification Sheet
SAMPLE TYPE NO.14
Soil No.1, Split B,Air - Dry Condition
REMAINDERS : 55, 17, 33, ii
45
S.H.R.P. Moisture Content Proficiency Sample Program
Laboratory Sub-Sample Identification Sheet
SAMPLE TYPE NO.15
Soil No. 2,Split A, Air - Dry Condition
46
S.H.R.P. Moisture Content Proficiency Sample Program
Laboratory Sub-Sample Identification Sheet
SAMPLE TYPE NO. 16
Soil No. 2, SplitB, Air - Dry Condition
REMAINDERS : 50, 64, 33, 46
47
48
Section 2
Master Data Record
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Returned Data Sheets
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Returned Tare Weights
LAB No. 1
SET # SAMPLE BAG WT. SET # SAMPLE BAG WT.
1 5 A 7.8 13 2 A 7.3
B 7.7 B 7.6
C 7.3 C 7.4
2 3 A 7.1 1416 A 7.9
B 7.6 B 7.9
C 7.7 C 7.9
312 A 7.7 1511 A 8.3
B 8.1 B 8.2
C 8.5 C 7.9
4 13 A 7.1 16 7 A 7.2
B 7.1 B 7.6
C 7.0 C 7.3
5 4 A 9.7
B 8.2
C 9.1
615 A 7.4
B 7.9
C 7.5
7 14 A 7.7
B 7.3
C 7.4
8 9 A 8.3
B 8.0
C 7.7
910 A 7.4
B 7.6
C 7.7
10 6 A 7.4
B 7.7
C 7.7
11 1 A 7.6
B 7.4
C 7.1
12 8 A 7.7
B 7.6
C 7.1
95
LAB No. 2
1. 9a-8.5 14.10a-8.3
9b-7.6 10b-8.5
9c-8.1 10c-8.1
2. 3a-7.4 15. lla-9.1
3b-7.7 11b-8.9
3c-7.411c-8.2
3. 16a-7.9 16. 5a-7.2
16b-7.9 5b-7.6
16c-7.8 5c-7.8
4. 12a-8.4
12b-8.0
12c-8.1
5. 13a-7.3
13b-7.5
13c-7.6
6. 8a-7.9
8b-7.9
8c-7.8
7. 15a-8.0
15b-7.6
15c-7.5
8. 2a-7.1
2b-7.2
2c-7.8
9. 14a-7.4
14b-7.4
14c-7.5
10. la-7.2
lb-7.4
lc-7.4
11. 7a-7.6
7b-7.2
7c-7.3
12. 4a-8.5
4b-7.8
4c-8.0
13. 6a-7.4
6b-7.4
6c-7.5
94
LAB No.4
SAMPLE # BAG WEIGHT SAMPLE # BAG WEIGHT
10 A 8.08 6 A 7.20
B 7.60 B 7.24
C 7.57 C 7.31
3 A 7.60 1A 7.15
B 7.28 B 7.43
C 7.17 C 7.10
9 A 7.37 16 A 7.40
B 7.67 B 7.33
C 7.24 C 7.76
13 A 7.07 11 A 8.17
B 7.03 B 8.45
C 7.40 C 9.02
7 A 7.59
B 7.52
C 7.27
8 A 7.34
B 7.23
C 7.22
15 A 7.38
B 7.78
C 7.71
2 A 7.51
B 7.05
C 7.48
12 A 7.87
B11.41
C7.90
5 A 7.36
B 7.61
C 7.36
14 A 7.61
B7.18
C 7.22
4 A 7.67
B7.86
C7.66
95
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102
APPENDIX I,II
October 17, 1990
Robin High
TRDF
2602 Dellana Lane
Austin, TX 78746
Dear Robin:
Subject: SHRP Soil Moisture Proficiency Sample Program.
Enclosed is a report which summarizes implementation activities
to date concerningthe subject program. All test data sheets
are contained under the blue page titled Section 3,Returned Data
Sheets. Information needed to construct the data array for a
components of variance analysis as previously discussed is
contained in other sections of the report.
Please proceed with the analysis as soon as possible. As
indicated in the past,participating laboratories should be
identified only by a number in the final report compiled for
distribution tointerested parties.
Call me if anythinghas been overlooked or further elaboration is
needed. I will review the analysis report upon receipt and
contact you by telephone if questions arise.
Yours very truly
Garland W. Steele, P.E.
President, Steele Engineering, Inc.
enclosure: SHRP Soil H20 Proficiency Sample Report
cc: Adrian Pelzner (letteronly)
105
Box 173 Tornado, West Virginia 25202 • Tele. (304) 727-8719
APPENDIX IV
January ii,1991
Virgil Anderson
48 Oaks Place
Lago Vista,TX 78645
Dear Virgil:
Subject: SHRP Soil Moisture Proficiency Sample Program.
This will confirm the substance of telephone discussions with
Robin duringthe past few days concerning the format for
presentingprecision data which can be determined from the
analyses now underway of test data from the subject program.
The most desirable approach is to use a format that is generally
used by AASHTO and ASTM. Examples are contained in ASTM C670,
Standard Practice for PreparingPrecision and Bias Statements for
Construction Materials. For example, if the analysis yields an
estimate of 2.1%for _ within laboratories by single operators,
the statement could read-
Precision-The within laboratory single operator standard
deviation has been found to be 2.1%.A Therefore, results of
two properly conducted tests by the same operator in the
same laboratory on the same soil with the same moisture
content should not differ by more than 5.94%.A
AThese numbers represent,respectively,the IS and D2S
limits as described in ASTM Practice C670, for Preparing
Precision Statements for Test Methods for Construction
Materials.
The data available from the subject program will, of course,
yield considerably more information concerning the components of
variance and, as discussed with Robin,will hopefully allow an
estimate of bias to be determined.
As originally discussed during the design of this program, the
within sample variance could be quantified by comparing the odd
numbered (i through 63) samples to the even numbered (2 through
64) samples for each of the 16 sample types. The between sample
variance could be quantified by comparing the first two samples
(I and 2) of each group of four samples to the second two samples
(3 and 4) of the same group of four etc. for all 16 groups of
four in each of the 16 sample types. Likewise, the within
material-same condition variance can be quantified by comparing
the 64 samples from split A to the 64 samples from split B for
each of the 8 pairs of A and B splits.
Box 173 • Tornado, West Virginia 25202 • Tele (304) 727-8719 1 09
In addition,the within material-different condition variance of
variances could be quantified by comparing the variance of the
128 samples from sample types I and 2 to the variance of the 128
samples from sample types 5 and 6 and similarly for each of the
other three sets. Further the between material-same condition
and the between material-different condition variance of
variances could be quantified in a similar manner.
Each of the above would provide valuable insight to SHRP and to
other researchers and practitioners concerning a necessary and
widely used test procedure.
Enclosed is a copy of a proposed revision to ASTM D2216 which
Adrian suggested should be made available to you and Robin for
information. Note particularly section 13on page ii of the
proposed revision. Apparently, SHRP results will provide
information of considerable interest to those responsible for
such standards.
Please call if you have further suggestions or ifmy terminology
needs clarification.
I appreciate very much your and Robin's efforts to expedite the
statistical analyses necessary to allow the highest and best use
of data now available from this program.
Yours very truly
Garland W.Steele, P.E.
President, Steele Engineering Inc.
enclosures: 12 pages
cc: Robin High
Adrian Pelzner (letter only)
Bill Hadley (letter only)
110
February 7, 1991
Virgil Anderson
48 Oaks Place
Lago Vista, TX 78645
Dear Virgil:
Subject: SHRP Soil Moisture Proficiency Sample Program.
This will confirm the substance of a previous telephone
discussion with Robin concerning an "AMRL style" scatter diagram
report to be distributed to the participants in the subject
program.
Enclosed, as promised, is a copy of some information concerning
such reports. It is my understanding, based on discussions with
AMRL, that the quadrants are now formed by intersecting mean
lines rather than intersecting median lines. Also, that
laboratory results eliminated (last paragraph of attachment) are
those results outside the 3a limits of the data as calculated
using all results. The remaining results are then recalculated
and no further eliminations are made.
Such a report would only be compiled after the currently
scheduled analyses are completed.
Please let me know if there are any questions or recommended
modifications to the above.
Yours very truly
Garland W.Steele
President, Steele Engineering, Inc.
cc: Adrian Pelzner(letter only)
Bill Hadley(letter only)
Box 173 • Tornado, West Virginia 25202 Tele. (304) 727-8719 111
APPENDIX V
TECHNICAL MEMORANDUM
TRDF SHRP LONG TERM PAVEMENT PERFORMANCE PROGRAM
TECH MEMO: AU-181 ._,_/DATE: June12,1991
AUTHOR: Robin High _&/_L_ FILE: P-O01
DISTRIBUTION: Garland Steele, Bill Hadley
SUBJECT: Variance Components and Bias Estimation for SHRP Moisture Content
Proficiency Sample Program
This memorandum s-mmarizes the test results from the analysis of the SHRP
moisture content proficiency sample program. When a test procedure is applied
repeatedly to a set of identical material samples the same results rarely
occur. An experimental design was structured to evaluate this variability
when testing both aggregate and soil material samples for moisture content.
Its purpose is to present the within-laboratory and between-laboratory
variance components estimated from the data collected during this experiment.
The different factors of the experiment which represent sources of
variability and how the materials were to be processed in each laboratory were
originally developed as Design 4 in Technical Memorandum AU-95 (Ref I). The
analysis of data from these designs were described in Technical Memorandum
AU-108 (Ref 2). The word "material" in this analysis represents both
aggregate and soil samples and will be used throughout this report to refer
to the applicable type of sample.
Due to the lack of an accepted reference value, an estimate of the amount
of bias in the testing procedure for moisture content in the samples has not
previously been evaluated. This study presents a unique opportunity to
estimate the amount of bias due to the moisture measurement process. Results
corresponding to this portion of the study will also be provided.
DATA DESCRIPTION
A brief description of the data is included in this report for
completeness. Further details are available in the AMRL report (Ref 3). In
this document a description of the experimental design, testing procedures,
2602DelIanaLane Austin,Texas Telephone 512/327-4211 • Fax512/328-7246
11S
and and a list of all of the data provided by AMRL collected by the 17
laboratories who participated in the experiment were provided.
Twotypes of material were used in the experimental plan (aggregates and
soils). For both aggregates and soils, material from two different sources
was acquired for the study. At each of the two levels of the factor
representing the source of the material (MATL) the batch was randomly split
into two portions (A or B).
For one-half of each split, moisture was added to the samples; the
remaining samples were air dried. One level of the moisture factor refers to
the Saturated Surface Dry (SSD) condition for aggregates and Plastic Limit
(PLM) condition for soils. The other level for each material refers to the
air dry condition.
Table i gives a brief summary the factors in the design. Sixteen
different types of samples were created and then shipped to the laboratories.
Sample numbers i through 4 refer to aggregates in the wet condition and
samples 5 through 8 refer to aggregates in the dry condition. Sample numbers
9 through 12 refer to soils in the wet condition and 13 through 16 refer to
soils in the dry condition. Each laboratory received 3 sets of the nearly
identical subsamples from each of the sixteen samples processed by AMRL.
Since the magnitude and the variability in the test results for soils was much
larger than for aggregates, two separate analyses for each type of material
will be given.
VARIANCE COMPONENT ANALYSIS
The experimental plan was developed to estimate the variance components
associated with testing the moisture content of both aggregate and soil
samples. Three replicate sets of material samples for each combination of the
design factors were provided to the seventeen laboratories.
The analysis phase for the determination of moisture content first
creates an analysis of variance table (ANOVA). The results are then used to
116
Table I. Factor levels and sample type identification.
FACTOR DESCRIPTION TYPE OF EFFECT
MST Moisture Fixed
MATL Material Fixed
LAB Laboratory Random
SAMPLE
TYPE NO. SAMPLE DESCRIPTION
AGGREGATES
SSD Condition
i .......................... Aggregate i, Split A
2 .......................... Aggregate i, Split B
3 .......................... Aggregate 2, Split A
4 .......................... Aggregate 2, Split B
Air Dry Condition
5 .......................... Aggregate I, Split A
6 .......................... Aggregate I, Split B
7 .......................... Aggregate 2, Split A
8 .......................... Aggregate 2, Split B
Aggregate I: WA - Supplied by University of Reno, Nevada
Aggregate 2: PL - Supplied by University of Reno, Nevada
SAMPLE
TYPE NO. SAMPLE DESCRIPTION
SOILS
Plastic Limit Condition
9 .......................... Soil i, Split A
i0 .......................... Soil i, Split B
Ii .......................... Soil 2, Split A
12 .......................... Soil 2, Split B
Air Dry Condition
13 .......................... Soil I, Split A
14 .......................... Soil i, Split B
15 .......................... Soil 2, Split A
16 .......................... Soil 2, Split B
Soil i: MI - Supplied by Department of Highways, Maryland
Soil 2:M2 - Supplied by Department of Highways, Maryland
117
estimate the magnitudes of the between- and the within-laboratory testing
variations (a2L,S and 02respectively) for both types of materials.
Estimation of the Variance Components
The experimental design under which the data were collected has a direct
impact on how the statistical analysis should proceed. The statistical model
used to summarize these data takes the following form:
MSTLAB - _ + MST + MATL + LAB + SPLT(MATL) + ERROR
The terms MST, MATL, and SPLT(MATL) remove the variability due to the
planned moisture content and material type. This allows more accurate
estimates of the random variation due to laboratories (LAB) and the random
variation due to other unknown factors (ERROR).
Tables 2 and 3 provide the Analysis of Variance (ANOVA) tables for the
results. From these summary statistics the two variance components
representing the between-laboratory (_LAB) and the within-laboratory (0"2)
components are estimated and appear in the lower portion of the tables.
Differences Among Means
Tables 2 and 3 are also used to identify the laboratories which produce
statistically different results from other laboratories. The average test
results from each laboratory are presented in a column and are ranked from
largest to smallest. Groups of laboratory means are underlined to indicate
which ones are not statistically different from one another. The averages to
be most concerned with are those which lie on either end of the row. If one
continuous line does not appear underneath these averages, there is evidence
to suggest the mean from that laboratory exceeds the two standard deviation
control limits and does not conform with the remainder of the data.
The mean results from laboratory 17 for aggregates appears to be
considerably smaller than the means from the other laboratories. A closer
118
Table 2.Variance component analysis for aggregate samples.
Degrees of Sum of Mean
Source Freedom Squares Square F Value Pr > F
....................................................................
Model 18659.049 36.6138 470.41 0.0001
MST i 614.220 614.2196 7891.49 0.0001
MATL I 43.343 43.3428 556.87 0.0001
LAB 16 1.486 0.0929 1.19 0.2699
Error 385 29.966 0.07783
Corrected Total 403 689.015
Variance Components
OaLAB= 0.0006345
02 =0.07783
Student-Newman-Keuls test for variable: MSTLAB
Means with the same underline are not significantly different.
SNK Grouping Mean LAB
1 5937 09
1 5583 07
1 5562 01
1 5467 04
1 5467 12
1 5438 15
1.5246 16
1.5221 05
1.5208 02
1.5154 06
1.5096 08
1.4974 14
1.4909 13
1.4871 03
1.4817 i0
1.4379 Ii
I1.1677 17
119
Table 3. Variance component analysis for soil samples.
Degrees of Sumof Mean
Source Freedom Squares Square F Value Pr > F
.....................................................................
Model 18 66999.245 3722.180 292.19 0.0001
MST I 45014.471 45014.471 3533.67 0.0001
MATL I 21723.755 21723.755 1705.33 0.0001
LAB 16 261.019 16.314 1.28 0.2059
Error 388 4942.622 12.739
Corrected Total 406 71941.867
Variance Components
CY2LAB-- O.1493
a2=12. 739
Student-Newman-Keuls test for variable: MSTLAB
Means with the same underline are not significantly different.
SNK Grouping Mean N LAB
17.628 24 ii
17.621 23 13
17.583 24 09
17.554 24 Ol
17.390 24 14
17.354 24 07
17.301 24 02
17.252 24 04
17.154 24 08
17.017 24 03
16.780 24 16
16.598 24 15
16.255 24 06
15.932 24 17
15.904 24 12
15.388 24 i0
14.95824 05
120
examination of the raw data for this laboratory is required to determine a
reason for this difference.
PRECISION STATEMENTS FOR MOISTURE CONTENT
The within laboratory variance components for the moisture contents of
the two material types are given in Tables 2 and 3. This section provides the
within-laboratory precision statements for moisture content testing. The two
standard deviation limits for the difference between two observations are
given. These values imply that within one laboratory, a pair of measurements
selected at random will differ by more than 2 4/-_ in only 5% of all cases.
Aggregates
Precision - The within-laboratory single operator standard deviation for
aggregates is determined to be _ - J 0.07783 B 0.2790.
Therefore, results of two properly conducted tests by the
same operator in the same laboratory on this aggregate should
not differ by more than 2 4_ - 0.7891 from each other.
These numbersrepresent, respectively, theIS and D2S limits as described
in ASTMPractice C670, for Preparing Precision Statements for Test Methods for
Construction Materials.
Soils
Precision - The within-laboratory single operator standard deviation for
aggregates has been found to be _ - J 12.739 _ 3.5692.
Therefore, results of two properly conducted tests by the
same operator in the same laboratory on this aggregate should
not differ by more than 2 J 2 _ =10.0951 from each other.
These numbers represent, respectively, the IS and D2S limits as described
in ASTMPractice C670, for Preparing Precision Statements for Test Methods for
Construction Materials.
121
BETWEEN LABORTORIES PRECISION STATEMENTS FOR MOISTURE SAMPLES
The between-laboratory variance components for the moisture content of
the two material types, are given in Tables 2 and 3. This section provides
between-laboratory precision statements based on these results for resilient
modulus testing. The two standard deviations limits for the difference
between two observations from different laboratories are given. These values
imply that the difference between one measurement selected at random from each
of two laboratories will differ from each other by more than 2 _2(_LA B+02)
in only 5% of all cases.
A_EreEates
Precision - The between laboratory single operator standard deviation for
moisture content has been found to be JOaLA B + O 2=0.28012.
Therefore, the results of properly conducted tests from two
laboratories on the same aggregate should not differ by more
than 2 J2 (O2LAB + 02) -- 0.7923 from each other.
These numbers represent, respectively, the IS and D2S limits as described
in ASTM Practice C670, for Preparing Precision Statements for Test Methods for
Construction Materials.
Soils
Precision - The between laboratory single operator standard deviation for
moisture content has been found to be J_LA8+02 3.5900.
Therefore, the results of properly conducted tests from two
laboratories on the same soil should not differ by more than
2 J 2 (_2LA8+02) = 10.1541 from each other.
These numbers represent, respectively, the IS and D2S limits as described
in ASTM Practice C670, for Preparing Precision Statements for Test Methods for
Construction Materials.
122
ESTIMATION OF BIAS
The precision of the standard test method for the determination of
moisture content of aggregates and soils in a laboratory was the primary topic
of the two previous sections. These results showed the degree of mutual
agreement of individual measurements both within and across laboratories. The
accuracy of a test procedure takes the precision statements one step further.
It covers both the precision and bias of the test method. The bias of a
result, often called the systematic error, involves consistent deviations from
a reference value. That is, the mean of the test will consistently be larger
or smaller than its true value. Further explanations of precision and
accuracy can be found in the ASTM publication E177 (Ref 3).
In order to have a valid statement on the bias of a test procedure, a
reference value is required. Because data to support this requirement have
not been available no estimate of bias has ever been determined. If an
acceptable reference value for moisture content can be derived, then the data
obtained from these test results may be used in estimating the bias of the
test procedure.
The material samples, processed by AMRL, were bagged and shipped to the
participating laboratories. An important requirement for estimating moisture
content is to test the samples as soon as possible so that they do not remain
in the bags for long periods of time. They should also have been stored at
the proper temperature and kept away from direct sunlight. If any of these
conditions were not satisfied, the possible impact on the bias calculations
remains unknown.
Moisture samples constructed by AMRL were developed such that water was
added in a known quantity to one-half of the samples and no water was added
to the other half. Since no water was added to the "dry" samples, the
moisture determined by the test results in the laboratories for these samples
is the best estimate possible of the amount which occurs naturally in air-
dried material.
123
The following procedure for estimating the bias in the moisture content
test method for aggregates was followed. Each laboratory was sent 3
subsamples for each of the 8 samples of material for a total of 24 subsamples.
The only difference between sample i and sample 5 materials is the added
moisture content. The same association exists between sample pairs (2,6),
(3,7), and (4,8).
For each laboratory the average moisture content was found for the three
subsamples of material produced by AMRL for sample number i. This average was
added to the average moisture content found by each laboratory for sample
number 5. This total represents the best estimate of the average moisture
content contained in the "wet" samples. The average moisture content of the
3 subsamples for sample I as determined by the respective laboratory was
subtracted to determine a bias term. The same procedure was used for "wet"
samples 2 through 4 and "dry" samples 6 through 8.
The resulting means for the aggregate samples from the 17 laboratories
across the different levels of factors in the study are shown in Table 4. The
analysis of variance performed on these data is given in Table 5. The results
indicate that only a small amount of bias exists for the aggregate samples.
The overall average is 0.03113. This positive number indicates the
laboratories did not estimate as much water in the sample as one would have
expected to find. The individual means found in the right hand column of
Table 4 indicate most of the laboratories produced a positive bias with
laboratory ii having the largest bias of 0.1200. Another interesting result
is that material from source WA generally produced large positive results
(average - 0.0615) and material from source PL generally produced both
positive and negative results (average - 0.0007). Thus, the magnitude of the
bias depends on the source of material used.
The same procedure was also followed for the soils. Sample numbers 9
through 12 had specific amounts of moisture added by AMRL. The corresponding
pairs are given by sample numbers 13 through 16 left in the air-dry condition.
124
Table 4. _ Bias estimates for aggregate samples 1 through 8 (SSD condition).
H
S A
eT ............................................
L L L WA PL
A I ......................................................
B T A B C D Mean
01 0.14000 0.18000 0.08333 -0 10333 0.0750
02 0.17667 0.03667 0.16333 -0 06667 0.0775
03 0.16333 0.02667 0.04667 -0 06667 0.0425
.........................................................
04 0.04000 0.01000 0.03333 -0 13333 -0.0125
05 0.00000 0.01667 0.02667 -0 02333 0.005
.........................................................
06 0.02333 0.02000 -0.00333 -0 04667 -0.0017
.........................................................
07 -0.00333 0.09667 0.05667 -0 06667 0.0208
.........................................................
08 0.01667 0.01000 0.06333 -0 03667 0.0133
09 0.06667 0.02667 0.13333 -0 09667 0.0325
.............. , .......... ° .......... , .......... , .........
I0 0.02000 0.01000 -0.01333 -0 09000 -0.0183
.........................................................
ii 0.13333 0.15667 0.14000 0 05000 0.1200
.........................................................
12 0.10333 0.02667 0.ii000 0 01333 0.0633
I .............. ° .......... , .......... , .......... , .........
I 13 0.07333 0.10500 0.05333 -0 07333 0.0396
I 14 0.08000 0.00000 0.00667 -0 06167 0.00625
I .........................................................
I 15 0.03333 0.01333 -0.01667 -0 12000 -0.0225
I .........................................................
I 16 0.11333 0.03667 0.08333 -0 02667 0.05170
I .............. ° .......... , .......... , .......... , .........
I17 0.11333 0.02667 0.01333 -0 00667 0.03667
...........................................................
Averages 0.0761 0.0470 0.0576 -0 0562
..................... , .....................
0.0615 0.0007
...........................................
0.03113
.............................................
125
Table 5. Analysis of Variance for bias estimates in aggregate samples.
Degrees of Sum of Mean
Source Freedom Squares Square F Value Pr > F
.................................................................
Mode] 17 0.1576 0.00927 2.23 0.0143
LAB 16 0.0948 0.00592 1.43 0.1675
MATL i 0.0628 0.06281 15.14 0.0003
Error 50 0.2075 0.00415
Corrected Total 67 0.3650
Student-Newman-Keuls test for variable: BIAS
Means with the same underline are not significantly different.
SNK Grouping Mean N LAB
0.1200 4 II
0.0775 4 02
0.0750 4 01
0.0633 4 12
0.0517 4 16
0.0425 4 03
0.0396 4 13
0.0367 4 17
0.0325 4 09
0.0208 4 07
0.0133 4 08
0.0063 4 14
0.0050 4 05
-0.0017 4 06
-0.0125 4 04
-0.0183 4 I0
-0.0225 4 15
126
The resulting means for the soil samples from the 17 laboratories across
the levels of the factors in the study are shown in Table 6. The analysis of
variance performed on these data is given in Table 7. The results indicate
that a larger amount of bias exists for the soil samples, except now the
difference is the negative value of -0.9834. This negative number indicates
the laboratories overestimated the amount of water in the sample one would
have expected to find. The individual means found in the right hand column
of Table 6 indicate most of the laboratories produced a negative bias.
However, laboratory 05 has a very large positive overall bias term of 1.614.
Another interesting result is that material from source MI generally produced
positive results (average - 0.4749) and material from source M2 generally
produced large negative results (average - -2.4418). Thus, the magnitude of
the bias depends on the source of material used.
In sl,mmary, an interesting contrast emerges from these results. Bias is
positive for aggregates and therefore the laboratories did not estimate as
much water in the sample as one would have expected to find. The negative
bias for soils indicates the laboratories overestimated the amount of water
in the sample one would have expected to find. Also, for both aggregates and
soils the source of the material influenced the size and the magnitude of the
bias term.
PRECISION STATEMENTS FOR BIAS
The average laboratory bias components for the moisture contents of
aggregates and soils are given in Tables 4 and 6. These means provide the
basis for statements concerning the precision of the moisture content
estimate. The appropriate standard deviation to apply depends upon the
desired inference. Table 8 summarizes the calculations of the appropriate
mean squares. Given the data provided for this experiment, confidence
intervals for the true bias estimates will be provided.
127
Table 6. Bias estimates for soil samples 9 through 16 (PLM condition).
M
S A
PT.............................................
L L L MI M2
B T A B C D Mean
01 1.07667 -0.ii000 -2.70667 -3.10333 -i 2108
.............. , .......... , .......... , .......... ].........
02 1.66333 -0.39000 -3.52000 -2.65667 -i 2258
03 0.80333 0.21333 -5.23333 -3.47000 -I 9217
04 0.69667 -0.22333 -2.84667 -2.62667 -I 2500
05 0.92000 -0.07333 5.56667 0.04333 I 6142
.............. J .......... ,.......... ,.......... ,.........
06 0.80667 0.12000 -0.19667 -0.76333 -0 0083
07 1.13333 -0.04333 -3.30667 -2.95000 -i 2917
08 1.05333 -0.13333 -2.99667 -3.10000 -i 2942
09 1.52333 0.09000 -3.24000 -2.99333 -i 1550
I0 1.23333 -0.39333 -3.79000 -0.73333 -0 9208
ii 0.70000 0.19667 -3.94333 -2.97000 -i 5042
12 0.89333 0.36000 -0.26333 -0.96333 0 0067
........................................................
13 0.81000 -0.19000 -2.88667 -2.78667 -i 2633
14 I.I0000 0.67333 -2.94667 -3.29667 -i 1175
15 0.36333 -0.05000 -2.24000 -2.33667-i 0658
16 1.75667 0.33667 -4.23333 -3.87333 -i 5033
.............. ].......... i..............................
17 -0.38667 -0.38333 -4.02000 -1.63667 -I 6067
..... , .......... ........... . .......... . .......... , .........
Averages 0.9498 0.0000 -2.5178 -2.3657
..................... ......................
0.4749 -2.4418
...........................................
-0.9834
.............................................
128
Table 7. Analysis of Variance for bias estimates in aggregate samples.
Degrees of Sum of Mean
Source Freedom Squares Square F Value Pr > F
.................................................................
Model 17 188.612 11.0948 6.56 0.0001
LAB 16 43.993 2.7496 1.62 0.0966
MATL I 144.618 144.6181 85.46 0.0001
Error 50 84.6079 1.6922
Corrected Total 67 273.2194
Student-Newman-Keuls test for variable: BIAS
Means with the same underline are not significantly different.
SNK Grouping Mean N LAB
1.614 4 05
0.007 4 12
-0.008 4 06
-0.921 4 i0
-1.066 4 15
-1.117 4 14
-i.155 4 09
-1.211 40l
-1.226 4 02
-1.250 4 04
-1.263 4 13
-1.292 4 07
-1.294 4 08
-1.503 4 16
-1.504 4 ii
-1.607 4 17
-1.922 4 03
129
Table 8. Mean square calculations for the bias of aggregates and soils.
_GGREGATES
Sumof Mean
Source DF Squares Square
..............................................
Error 67 0.3650 0.005448
Corrected Total 67 0.3650
Total 68 0.4309
Sum of Mean
Source DF Squares Square F Value Pr > F
....................................................................
AGGR i 0.0628 0.06281 13.72 0.0004
Error 66 0.3022 0.004578
Corrected Total 67 0.3650
Total 68 0.4309
SOILS
Sum of Mean
Source DF Squares Square
.............................................
Error 67 273.2194 4.0779
Corrected Total 67 273.2194
Total 68338.9847
Sum of Mean
Source DF Squares Square F Value Pr > F
........ .............................................................
SOIL I 144.6180 144.6180 74.22 0.0001
Error 66 128.6013 1.9485
Corrected Total 67 273.2194
Total 68 338.9847
130
Precision Statements of Bias for Aggregates
Aggregates. Table 8 shows the within-laboratory single operator standard
deviation for aggregates is determined to be _ = J 0.005448
- 0.0738. Therefore, the bias of a properly conducted test
by one operator in the same laboratory on an aggregate
material should not differ by more than 2 o- 0.1476 from the
true value of the bias. When the experimental results were
compared with a known reference value, the 95% confidence
limits for the bias of a moisture test on an aggregate
material was found to lie between 0.0311 ± 2 a or (-0.116,
0.179).
Aggregates
from Source WA. The within-laboratory single operator standard deviation for
aggregates from source WA is determined to be a =J 0.004578
- 0.06766. Therefore, the bias of a properly conducted test
by one operator in the same laboratory on an aggregate from
this source should not differ by more than 2 _ - 0.1353 from
the true value of bias. A 95% confidence interval for the
bias of the moisture content of aggregates from this source
is 0.0615 ± 2 _ or (-0.074, 0.197).
Aggregates
from Source PL. The within-laboratory single operator standard deviation for
aggregates from source PL is determined to be a =_0.004578
= 0.06766. Therefore, the bias of a properly conducted test
by one operator in the same laboratory on an aggregate from
this source should not differ by more than 2 _ - 0.1353 from
the true value of bias. A 95% confidence interval for the
bias of the moisture content of aggregates from this source
is 0.0007 ± 2 oor (-0.135, 0.136).
These numbers represent, respectively, the IS and 2S limits as described
in ASTM Practice C670, for Preparing Precision Statements for Test Methods for
Construction Materials.
131
Precision Statements of Bias for Soils
Soils. Table 8 shows the within-laboratory single operator standard
deviation for soils is determined to be _ - J 4.0779 -
2.0194. Therefore, the bias of a properly conducted test by
one operator in the same laboratory on a soil material should
not differ by more than 2 _ - 4.0388 from the true value of
the bias. When the experimental results were compared with
a known reference value, the 95% confidence limits for the
bias of a moisture test on a soil material was found to lie
between -0.983 ± 2 _ or (-5.022, 3.056).
Soils from
Source MI. The within-laboratory single operator standard deviation for
soils from source MI is determined to be o = J 1.9485 =
1.3959. Therefore, the bias of a properly conducted test by
one operator in the same laboratory on a soil from this
source should not differ by more than 2 a = 2.7918 from the
true value of bias. A 95% confidence interval for the bias
of the moisture content of soils from this source is 0.475
± 2 aor (-2.317, 3.267).
Soils from
Source M2. The within-laboratory single operator standard deviation for
soils from source M2 is determined to be _ = J 1.9485 =
1.3959. Therefore, the bias of a properly conducted test by
one operator in the same laboratory on a soil from this
source should not differ by more than 2 a =2.7918 from the
true value of bias. A 95% confidence interval for the bias
of the moisture content of soils from this source is -2.442
± 2 O or (-5.234, 0.350).
These numbers represent, respectively, the IS and 2S limits as described
in ASTM Practice C670, for Preparing Precision Statements for Test Methods for
Construction Materials.
132
REFERENCES
I. High, R., "Materials Testing Sampling Designs", Technical Memorandum AU-
95, TRDF, December, 1989.
2. Anderson, V., "Analysis of Material Testing Sampling Designs", Technical
Memorandum AU-108, TRDF, January, 1990.
3. Uherek, G., "SHRP Moisture Content Proficiency Sample Program", AMRL,
October, 1990.
4. American Society .for the Testing of Materials, "Use of the Terms
Precision and Accuracy as Applied to Measurement of a Property of a
Material", E177, 1980.
133
APPENDIXVl
November !8_ 1991
Fred Martinez
South Western Laboratories
222 Cavalcade Street
PO Box 8768
Houston. TX 77249
Dear Fred:
Subject: SHRP Soil Moisture Proficiency Sample Program
Enclosed for your information is a copy of followingfourscatter
diagrams showing results of tests on the subject Program.
°Aggregate(SHRP Type !)-air dry condition
°Aggregate(SHRP Type I)-saturated surface dry condition
°Soii(SHRP Type II)-air dry condition
°Soii(SHRP Type II)-piastic limit condition
The vertical and horizontal lines on each diagram are the means
of the A and B samples respectively for each of the four
conditions noted above.
The test data derived by your laboratory is identified by the
letter H.
Yours very truly
Garland W. Steelej P.E.
President, Steele Engineering inc.
enclosure: 4 pages
co: Neii Hawks(letter only)
Paul Teng(letter only)
Dave Esch(ietter only)
Bill Hadley(letter only)
Robin High(letter only)
Box 173 Tornado, West Virginia 25202 • Tele (304) 727-8719 13 7
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APPENDIXVii
Moisture Content-Aqgregates
Precision
The within-laboratory single operator standard deviation for
moisture content of aggregates has been found to be _ = A0.2790%.
Therefore, results of two properly conducted tests by the same
operator in the same laboratory on the same type of aggregate
sample should not differ by more than 2_2 a= 80.7891%from each
other.
The between-laboratory single operator standard deviation for
moisture content of aggregates has been found to be _(a21_b+a 2) =
A0.28012%. Therefore,results of properly conducted tests from
two laboratories on the same aggregate should not differ by more
than 2_(2(_21ab+a2)) = 80.7923%from each other.
These numbers represent, respectively, the AIS and _D2S limits
as described in ASTM Practice C670,Preparing Precision
Statements for Test Methods for Construction Materials.
Bias
When experimental results are compared with known values from
accurately compounded specimens:
The bias of moisture tests on one aggregate material has been
found to have a mean of +0.0615%. The bias of individual test
values from the same aggregate material has been found with 95%
confidence to lie between -0.074%and +0.197%.
The bias of moisturetests on a second aggregate material has
been found to have a mean of +0.0007%. The bias of individual
test values from the same aggregate material has been found with
95%confidence to lie between -0.135%and +0.136%.
The bias of moisture tests overall on both aggregate materials
has been found to have a mean of +0.0311%. The bias of
individual test values overall from both aggregate materials has
been found with 95%confidence to lie between -0.116%and
+0.179%.
145
Moisture Content-Soil
Precision
The within-laboratory single operator standard deviation for
soils has been found to be a = A3.5692%. Therefore,results of
two properly conducted tests by the same operator in the same
laboratory on the same type soil should not differ by more than
2_2 _ = _i0.0951%from each other.
The between-laboratory single operator standard deviation for
moisture content of soils has been found to he _(a21ab+_2) =
A3.5900%. Therefore,results of properly conducted tests from
two laboratories on the same soil should not differ By more than
2_(2(a_l_h+a2)) = Bi0.1541%from each other.
These numbers represent, respectively, the _IS and _D2S limits
as described in ASTM Practice C670, Preparing Precision
Statements for Test Methods for Construction Materials.
Bias
When experimental results are compared with known values from
accurately compounded specimens:
Thebiasof moisture tests on one soil material has been found to
have a mean of +0.475%. The bias of individual test values from
the same soil material has been found with 95%confidence to lie
between -2.317%and +3.267%.
The bias of moisture tests on a second soil material has been
found to have a mean of -2.442%. The bias of individual test
values from the same soil material has been found with 95%
confidence to lie between -5.234%and +0.350%.
The bias of moisture tests overall on both soil materials has
been found to have a mean of -0.983%. The bias of individual
test values overall from both soil materials has been found with
95% confidence to lie between -5.022%and +3.056%.
146

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