- Email: [email protected]
Chapter 13 Water Quality Monitoring Networks
204 CHAPTER 13
WATER
QUALITY MON I TOR I NG NETWORKS i Y
Colorado State U ive
b y Thomas G. Sanders,
NECESS I T Y FOR NETWORKS Environmental
legislation
been responsible f o r recent streams.
Such m o n i t o r i n g
and
general
water
quality
awareness
have
increased m o n i t o r i n g a n d s a m p l i n g of water and
testing
can
be expensive
and
a
in
scientific
approach to m i n i m i z i n g costs w h i l s t m a x i m i z i n g b e n e f i t s i s d e s i r a b l e . The
assumption
trends
in
water
that
a
quality,
measure ambient
water
monitoring
actively
guide
implemented,
in
government's
however,
feasibi I i t y
obtaining
conclusive
compromises a n d
compliance etc.,
is
with
water
water
legal
the
view
being
is
the
of
more
which
to
When from
a
in
involved
resources force
of
for
water
efforts.
viewed
available
and
generated
problems
the consequences
detect
legislation
management
is,
can
standards,
into
The
monitoring
That
information w i t h measures,
stream
information
quality
quality
network
incorporated
conclusive
stand-point.
half
monitoring
the U n i t e d States.
envisages
technical
quality
check
quality,
water q u a l i t y management qua1 i t y
water
many
a r e often
not
f u l l y understood. Monitoring conducted
over
necessarily Simply
performed large
hydrologic
collecting
problem; cases, samples
or
ultimate
of
geographic
in
i n fact,
thought types
use
government
is
that
of
data
the
data.
(defined
covering
such
given
agencies
areas
boundaries)
samples
so major,
little
by
a
by
the
analysis
many
political
often
i t becomes a n end to
in
in
techniques
Consequently,
the
to
be
majority
a
used of
major
In many
itself. of
not
streams.
becomes
representativeness
cases,
and
k i lometres of
many
situation
is,
the
or
water
even
the
resources
are
devoted to c o l l e c t i n g d a t a as i t i s the most immediate problem. By
using
most
resources
to
physically
collect
water
resources a r e l e f t to consider the representativeness of a n d space,
d a t a a n a l y s i s o r d a t a use.
m o n i t o r i n g system system
should
be
should
therefore
examined
and
samples,
the sample
little i n time
A b a l a n c e d ( c o l l e c t i o n versus
be developed designed
so
use)
the e n t i r e m o n i t o r i n g
simultaneously
(a
systems
the
system
approach). The purpose of
t h i s chapter
i s to
review
monitoring
and
then d e l i n e a t e the impacts t h a t such a systems a p p r o a c h of m o n i t o r i n g w i l l h a v e on network design b y c o n s i d e r i n g the w a t e r q u a l i t y
v a r i a b l e s to
be
205 monitored,
the sampling location a n d s a m p l i n g frequency.
MONITORING SYSTEM FRAMEWORK
Before
a
monitoring
network
can
be
m o n i t o r i n g program should be delineated, I n addition,
the decisions
designed
the
goals
of
the
and specific objectives applied.
to be made based
upon
information
network and the subsequent actions should also be well
from
the
developed p r i o r to
the collection o r a s i n g l e b i t of data. The a c t u a l
operation
of
a m o n i t o r i n g system can
be
categorized
into
f i v e major functions:
1.
Sample Collection
2.
Laboratory Analysis
3.
Data H a n d l i n g
4.
Data A n a l y s i s
5.
I nformation U t i I i z a t i o n These f i v e functions serve as
quality
conditions
of
water
management
agency
approvals,
regulations,
qua1 i t y . effects
Without of
those
a
the feedback
quality
loop from
management
i s c o n s t a n t l y m a k i n g decisions pollution
monitoring
decisions,
abatement,
feedback
the
loop
(e.g.
etc.)
past
water
making.
r e l a t i v e to
that
accurately
management's
in-stream
decision
affect
and
site
water
documenting
success
A
the
future
direction are uncertain. M o n i t o r i n g network design operational collection
i s an o v e r r i d i n g a c t i v i t y
f u n c t i o n s l i s t e d above) (e.g.
location
that
a n d frequency)
should c a r e f u l l y with
used to o b t a i n the i n f o r m a t i o n r e q u i r e d a n d making.
Thus,
the
type
actually
( c o v e r i n g the f i v e i n t e g r a t e sample of
data
utilized
analysis
in decision
the design of water q u a l i t y m o n i t o r i n g networks must
i n t o account the decision m a k i n g process,
take
the t y p e and level o f s t a t i s t i c a l
a n a l y s i s a p p l i e d to the d a t a , a n d u l t i m a t e use of the d a t a collected. FACTORS I N NETWORK DESIGN M o n i t o r i n g network
design,
guides m o n i t o r i n g operations,
as a p l a n n i n g / d e s i g n can
i t s e l f be broken
componen ts:
1.
Selection of Water Q u a l i t y V a r i a b l e s to Monitor
2.
Sampling Station Location
type function
down
which
i n t o three m a j o r
206
3.
Sampling Frequency The
term
water
quality
variable
is
used
instead
of
water
quality
parameter because water q u a l i t y i s a random v a r i a b l e a n d c a n be d e f i n e d by
statistical
addition,
parameters
the term
deterministic
parameter
equations
a s the mean a n d
such or
is
most
models
often
and
standard
used
to
can
lead
it
deviation.
define
In
constants confusion
to
of by
i d e n t i f y i n g i t a s a random v a r i a b l e . the
monitoring
system's o p e r a t i o n a l f u n c t i o n s I i s t e d p r e v i o u s l y a n d v i c e versa.
Each
of
these
factors
The degree
of impact, however,
in
network
design
effects
all
depends upon the purpose a n d g o a l s of
the m o n i t o r i n g
system. SELECT ION OF WATER QUALITY VARIABLES TO MEASURE
to
The selection of the water q u a l i t y
v a r i a b l e to be sampled w i l l
a
of
l a r g e extent
background developing network
frame
the of
its
objectives reference
the o b j e c t i v e s
has
stndards, for
or
on
of
primary
the
of
the
sampling
the
individuals
monitoring
objective
to
network
network.
monitor
the
responsible
for
When
a
compliance
sampl i n g
with
stream
the v a r i a b l e s sampled a r e the ones s p e c i f i e d i n the l e g i s l a t i o n ,
example,
dissolved
(DO).
oxygen
DO
is
sampled
because
s t a n d a r d s specify a minimum l e v e l which should not be v i o l a t e d . s t a n d a r d l e g i s l a t i o n were those r e l a t e d to water s u p p l y , biochemical oxygen demand a n d dissolved solids,
(BOD),
stream
Dissolved
i m p o r t a n t a n d i n c l u d e d in stream
oxygen a n d o t h e r v a r i a b l e s deemed most
quality
depend
and
temperature,
col iform b a c t e r i a ,
turbidity,
and
suspended
because most i n d i v i d u a l s e n t e r i n g the f i e l d o f water
management d u r i n g
the
last
few
decades
have
a
background
in
s a n i t a r y engineering. Since i n d i v i d u a l s o t h e r t h a n besides s a n i t a r y became interested i n water q u a l i t y , which
should
be
sampled
( e n v i r o n m e n t a l ) engineers
the number of water
routinely
has
increased.
quality This
variables
compounding
syndrome cannot a n d should not be the major v a r i a b l e selection mode f o r a permanent,
routine
accommodated
in
sampling
the
p o p u l a r i t y of synoptic
much
program,
discussed
but
instead
synoptic
can
surveys.
be
The
easily
increasing
s u r v e y s w i t h s a m p l i n g agencies i s p r o b a b l y
due to
the f a c t t h a t the s u r v e y s a r e in fact a n a p p l i c a t i o n of a systems a p p r o a c h to
water
programs, sampling
quality
monitoring.
the objectives, frequency,
the
Unlike
the
permanent,
the use of the d a t a , variables
to
be
routine
the s a m p l i n g
sampled
as
well
sampling
locations, as
the
the data
207 analysis
procedures
and
decisions
to
be
made
should
be
developed
be
developed
completely before the survey i s undertaken. Both
sampling
independently
location
of
the
and
water
sampling
quality
frequency
variable
to
can
be
analyzed,
location and frequency a r e specified f o r the c o l l e c t i o n of ( t h e analyses a r e made l a t e r ) .
However,
water
monitored.
quality
week
at
a
monitoring
variable
single the
being
point
in
relatively
a
river
stable
For
may
river
the
variables
t h e i r n a t u r a l and/or
considered
when
be
more
temperature, coliform
sampling than
but
once
adequate
may
bacteria
water
delineated.
Network
concentration
qua1 i t y
is
concentration,
the
as
former
be
sample
in
if
opposed
being
a
to
an
result
24-hour
(generally
daily
in
space
In
several
period,
while
the daytime,
in a be to
should
be
(flow
weighted)
grab
samples the
can
addition
units
mean
instantaneous
of
for
hardly
be s p e c i f i e d so
time a n d
respective
a
a
concentrations.
should
network.
their
differs
measurements spaced d u r i n g a single
variation
monitoring
variables,
design
needed
the
to be monitored
man-made
designing
considering
only a
example,
before a water q u a l i t y m o n i t o r i n g network can be designed
systematic fashion, that
both
both c r i t e r i a a r e affected b y the
adequate for m o n i t o r i n g r a p i d l y v a r y i n g Therefore,
as
the water sample
sample
with
latter
flow
comprises a.m.
between 8.00
and
4.30 p.m.1. In
reality,
the
specification
of
the
water
quality
variable
however, water
to
be
In p r a c t i c e ,
monitored p r i o r to i n i t i a t i n g network design would be ideal.
network design i s specified a n d one must know o r determine what
quality
variables
can
be
accurately
monitored
with
the
existing
a
water’
network.
SAMPL I NG STAT ION LOCAT ION The
location
of
m o n i t o r i n g network design,
a
permanent
i s probably
b u t a l l too often
never
comprises lead i n many cases r i v e r g a u g i n g stations. the
gauging
sampled
is
collectors
station not
and
follow
when
most
properly
is
truly
addressed.
representative generally
of
the
water
the
in
aspect
of
quality
the
Expediency
network a n d cost
near existing
Whether the s i n g l e g r a b sample from the b r i d g e o r but
users
station
critical
to s a m p l i n g from b r i d g e s o r
known,
e s t i m a t i n g discharge, indicate exactly
sampling
the
is
quality
of
the
assumed data.
measuring
discharge.
water
quality
However, variable
be
Using
measurement anywhere i n the river
water to
lateral
t h i s does
mass
being
by
both
the
river
stage
for
transect not
would
necessarily
concentrations.
In
fact
208
F i g , 13.1
Macrolocation of Sampling Stations W i t h i n a R i v e r Basin Using the Percent Areal Coverage a s the C r i t e r i a S p e c i f y i n g Locat ion
209 research
indicates
the
opposite,
that
will
rarely
a
single
sample
be
i n d i c a t i v e of the average water q u a l i t y i n a r i v e r cross section. Sampling
locations
for
a
c l a s s i f i e d i n t o two levels of
permanent design:
water
quality
network
former
b e i n g a f u n c t i o n o f the specific objectives o f the network
latter
being
independent
of
can
be
macrolocation a n d microlocation,
the
objectives
but
a
the
and
the
of
the
function
representativeness of the water sample to be collected. The political etc.
macrolocation
within
boundaries,
a r e a s of
Macrolocation can
a
river
basin
usually
major p o l l u t i o n
be specified,
coverage u s i n g b a s i n c e n t r o i d s
a s well,
(Sanders et
is
loads,
determined
population
a c c o r d i n g to percent
1986).
al,
This
locates sampling p o i n t s in a systematic f a s h i o n m a x i m i z i n g the e n t i r e b a s i n w i t h a few s t r a t e g i c a l l y an
example
of
locating
sampling
using
areal
methodology
information of F i g u r e 13.1
located stations.
stations
by
centres,
basin
centroids
is and
sub-basin centroids w i t h percent a r e a l coverage a s the c r i t e r i a . The procedure f o r l o c a t i n g sampling s t a t i o n s i s d e r i v e d b y d e t e r m i n i n g the c e n t r o i d o f a r i v e r system. i s a stream
without
defined
i n t e r i o r stream r e s u l t i n g from
value
equal
to
the
i s given
intersection
of
the v a l u e o f two e x t e r i o r
(this
one;
an
tributaries
Continuing downstream i n the same manner,
would have a v a l u e of two. streams intersect,
Each c o n t r i b u t i n g e x t e r i o r t r i b u t a r y
tributaries)
as
the r e s u l t a n t downstream s t r e t c h of r i v e r would h a v e a the
sum
of
the
values
of
the
preceeding
intersecting
stream. At the mouth of the r i v e r , the v a l u e o f the f i n a l r i v e r section w i l l be equal to the number o f c o n t r i b u t i n g e x t e r i o r t r i b u t a r i e s ,
22 in F i g u r e
13.1.
by
D i v i d i n g the
v a l u e of
the f i n a l
v a l u e of the c e n t r o i d of the b a s i n ,
s t r e t c h of
1 1 i s calculated.
h a v i n g a v a l u e equal to t h a t of the c e n t r o i d sections and
i s the
location of
the
the
river
r i v e r basin, of
I n many
sampling station
cases,
when
with
When
this
occurs,
closest to the c e n t r o i d i s chosen.
the
stream
highest
the
initial
river
basin
centroid.
segment
having
the two equal The
two
order
the mouth
t h i s procedure to
The n e x t o r d e r o f sampling
determined b y f i n d i n g the c e n t r o i d v a l u e of a n d below
applying
into
there i s u s u a l l y not a stream h a v i n g a v a l u e e q u a l to
the centroid.
the
The section of r i v e r
d i v i d e s the b a s i n
( t h e assumption i s made t h a t there e x i s t s a s a m p l i n g s t a t i o n a t of the r i v e r b a s i n ) .
two,
a
a
that value
locations
is
sections above
procedure
is
continued
u n t i l a percentage of a r e a l coverage i s a t t a i n e d . The percentage of area coverage specified b y the m o n i t o r i n g agency defined as the number of
sampling
the
this
basin.
sampling
Intrinsic
in
station hierarchy
stations d i v i d e d b y
objective
that
procedure
o r d e r s the
is
importance
is
the m a g n i t u d e of the of
concept each
of
a
sampling
210 station
in the b a s i n
1973). T h i s p r o v i d e s a
(Sharp,
r e a l i s t i c methodology
i n which a r a t i o n a l implementation progam c a n proceed: stations
(highest
available,
order)
additional
are
built
first
and
as
the most
the
important
resources
become
As each succeeding h i e r a r c h y
s t a t i o n s can be b u i l t .
of s t a t i o n s a r e e s t a b l i s h e d the percentage of a r e a l coverage i s increased. Having
established
microlocation
the
specifies
macrolocations
the
river
within
reach
to
a
be
river sampled
microlocation specifies the p o i n t i n the r e a c h to be sampled.
basin,
the
while
the
This point
is
t h e location of a zone in the r i v e r r e a c h where complete m i x i n g e x i s t s a n d
in o r d e r to o b t a i n a
o n l y one sample i s r e q u i r e d from the l a t e r a l transect
(in
representative
space)
sample.
Being
downstream from the nearest o u t f a l l ,
a
function
t h e zone of
of
the
distance
complete m i x i n g can
be
estimated u s i n g v a r i o u s methodologies. Given the assumptions t h a t a p o i n t
source
stream approximates a Gaussian d i s t r i b u t i o n , modelled
using
image
theory,
in a
d i s t a n c e downstream
the
following
straight,
pollutant
a n d t h a t b o u n d a r i e s can equation
u n i f o r m channel
-
-
(J
Y
where
a point
L
Y
be the
source
1977).
2u
(13.1) is
the
from
mixing
source
velocity and D Estimates of D
Y
predict
2oy
distance
D
can
from
p o l l u t a n t to a zone of complete m i x i n g (Sanders et a l . ,
LY
in a
distribution
Y
Y
to
distance farthest
for
complete
lateral
lateral
boundary,
u
mixing,
a y
is
stream
mean
is
i s the l a t e r a l t u r b u l e n t d i f f u s i o n coefficient. can be made u s i n g e q u a t i o n 13.2
= 0.23 du'
(13.2)
where d i s depth of flow u* i s shear v e l o c i t y
g
i s acceleration flow
due to g r a v i t y R i s h y d r a u l i c r a d i u s S i s slope o r t h e h y d r a u l i c g r a d i e n t (Sanders e t al., Unfortunately,
1977). there may not e x i s t
in a g i v e n r i v e r
of complete m i x i n g due i n p a r t to the random n a t u r e of
mixing
distance,
determination of
inapplicability
of
the m i x i n g distance,
the
assumptions
o r more often
river
l e n g t h o r t u r b u l e n c e to assure complete m i x i n g
river
reach.
On
the o t h e r
hand field
reach any
within
in
used
t h a n not,
v e r i f i c a t i o n of
points
the aforementioned not
the
enough
the s p e c i f i e d
a completely
mixed
zone p r i o r to l o c a t i n g a permanent s a m p l i n g s t a t i o n c a n be e a s i l y done b y collecting
m u l t i p l e samples
in the cross
u s i n g a we1 I-known one- o r two-way
section
and analyzing
the
a n a l y s i s of v a r i a n c e techniques.
data
21 1 If
there
sampled,
is
not
a
completely
mixed
zone
the
in
river
reach
to
be
there a r e three a l t e r n a t i v e s :
( 1 ) Sample anyway a t a s i n g l e p o i n t a n d assume i t i s r e p r e s e n t a t i v e ( t h i s i s a general approach adopted t o d a y ) ;
( 2 ) Don't sample the r i v e r reach a t a l l , obtained does not q u a l i t y o f the
represent
sample
because t h e d a t a w h i c h would be
the e x i s t i n g r i v e r
quality,
b u t only
In o t h e r words,
volume collected.
the
the data
is
useless;
( 3 ) Sample a t several p o i n t s in the l a t e r a l transect c o l l e c t i n g a composite mean, which would be r e p r e s e n t a t i v e of the water q u a l i t y
in the r i v e r
a t that p o i n t i n time a n d space.
I f the sample i s not r e p r e s e n t a t i v e of the water mass, sampling
as
presentation
well and
as the
the
mode
realistic
m a k i n g becomes inconsequential.
of
use
data of
analysis,
the
data
interpretation
for
I n s p i t e of t h i s f a c t ,
the frequency of
objective
and
decision
c r i t e r i a to e s t a b l i s h
s t a t i o n locations f o r r e p r e s e n t a t i v e s a m p l i n g h a v e received r e l a t i v e l y
little
a t t e n t i o n from many i n s t i t u t i o n s a n d agencies responsible f o r water q u a l i t y monitoring. SAMPLING FREQUENCY Once sampling
stations
a r e representative
have been
i n space,
located to ensure
sampling
frequency
samples collected
should
be
specified
so
t h a t the samples a r e r e p r e s e n t a t i v e in time. Sampling frequency basin
is
a
very
a t each permanent
important
parameter
sampling station w i t h i n a
which
must
be
considered
design of a water q u a l i t y m o n i t o r i n g network.
A l a r g e p o r t i o n of
o f o p e r a t i n g a m o n i t o r i n g network
r e l a t e d to
sampling.
However,
the
reliability
d e r i v e d from a m o n i t o r i n g network sampling.
Addressing
is directly
this
and
utility
of
river in
the
the costs
the frequency
water
quality
of
data
i s l i k e w i s e r e l a t e d to the frequency of
anomaly
Quimpo
(1968)
summarized
the
s i g n i f i c a n c e of sampling frequency a n d stated t h a t : On the one hand,
b y s a m p l i n g too often,
obtained i s r e d u n d a n t and t h u s expensive, hand,
the i n f o r m a t i o n a n d on the other
sampling too i n f r e q u e n t l y bypasses some i n f o r m a t i o n
necessitating an extended p e r i o d of observation. Significant v i o l a t ion
,
as
sampling
frequency
is
m a i n t a i n i n g e f f I uent standards,
i n ambient water q u a l i t y ,
very
to
detecting
stream
standards
a n d e s t i m a t i n g temporal changes
l i t t l e q u a n t i t a t i v e c r i t e r i a which designate
a p p r o p r i a t e sampling frequencies h a v e been a p p l i e d to the design of water
21 2 quality
monitoring
networks.
many
In
cases,
professional
judgment
cost c o n s t r a i n t s p r o v i d e the b a s i s f o r s a m p l i n g frequencies.
All
frequencies
upon
are
capabilities, only
the
same
at
once-a-month,
practical
means
each
station
once-a-week,
to
implement
etc.
a
frequencies
as
and
1978).
Adrian,
functions
of
the
variable
(Nyquist frequency),
maximum
to
minimum
flow
cyclic
methods
variations
and
(Ward et
possibly
the
considering
the
include
of
the
b a s i n area
water
and
19671,
Orlob,
specifying
of
a
test
measuring
the
confidence
1976; L o f t i s a n d Ward,
al,
water
quality
the r a t i o of
quality
intervention
1978),
1978), and
the number of d a t a p e r y e a r f o r hypotheses (Sanders and Ward, the power
routing
s a m p l i n g frequencies a t each
The
the d r a i n a g e
(Pomeroy
i n t e r v a l o f the a n n u a l mean
although
program
too often,
there do e x i s t many q u a n t i t a t i v e ,
s t a t i s t i c a l l y meaningful procedures to specify (Sanders
based
and
sampl i n g
s t a t i s t i c a l b a c k g r o u n d o f d a t a collectors, station
and
and
(Lettenmaier,
1975).
A l l of the aforementioned procedures can b e a p p l i e d to the design of a water q u a l i t y m o n i t o r i n g network w i t h each r e q u i r i n g a d i f f e r e n t statistical
sophistication
assumptions app I y One of variable
the
.
simplest
(iid)
and
as
approaches
concentrations
distributed
insofar
are
is
data
to assume
random,
determine
the
requirements that
the
independent
number
of
as
well
water
and
samples
level of as
quality
identically
per
year
as
a
f u n c t i o n o f an a l l o w a b l e ( s p e c i f i e d ) confidence i n t e r v a l of the mean a n n u a l concentration analyses of
( t h i s i s analogous to the procedure f o r d e t e r m i n i n g how many a
water
sample
should
be
made
to
determine
a
reasonable
estimate o f the mean water q u a l i t y v a r i a b l e c o n c e n t r a t i o n ) .
[
n =
aizS]
(13.3)
where n i s the number of e q u a l l y is a
constant
number
of
which
samples,
is a
S
is
spaced samples collected p e r y e a r ,
function the
of
the
standard
l e v e l of
deviation
concentrations a n d R i s s p e c i f i e d h a l f - w i d t h
of
significance of
the
water
the confidence
taI2
and
the
quality
interval
of
the a n n u a l mean. Using the same assumption,
t h a t the water
number of samples p e r
year
can
a n a l y s i s procedure as
well.
For
quality
be s p e c i f i e d a s a example,
if
variable i s iid, function
annual
of
means
tested f o r s i g n i f i c a n t changes u s i n g the d i f f e r e n c e in means,
the
the data
were
to
be
then to detect
a n assumed level of change, t h e number of samples c a n be specified.
A
more
sophisticated
procedure,
representing
a
higher
level
of
21 3
0.9
0.8
R vs. Number of Somples per Yeor I 2 3 4 5 6 7 8
0.7
0.6
Wore Conn. at Thompsonville Deerfield Conn. ot Montopue City Millers Conn.ot Vernon
Westfield Conn. ot Turners Falls
R
0.5
0.4
0.3
0.2
0. I
I
10
1
20
I
30
I
40
I
50
Number of Somples per Yeor
Fig 13.2
A p l o t n u m b e r o f s a m p l e s per y e a r of the expected h a l f - w i d t h of t h e c o n f i d e n c e i n t e r v a l of m e a n log f l o w , R , v e r s u s n u m b e r of S a m p l e s for S e v e r a l R i v e r s in t h e C o n n e c t i c u t R i v e r B a s i n
214 statistical
analysis,
may not be i i d ,
would
be
to recognize
b u t h i g h l y dependent,
that
water
seasonal v a r i a t i o n ,
a n d determine s a m p l i n g frequency
variability
water
of
the
quality
p e r i o d i c components h a v e daily
discharge,
data
been
variable
removed.
bases
of
quality
veriables
not i d e n t i c a l l y d i s t r i b u t e d ,
as a f u n c t i o n of
series
after
trend
Unfortunately,
other
than
water
time
having
quality
number, r e l i a b i l i t y a n d l e n g t h a r e g e n e r a l l y
variable
of
the and
mean
sufficient
not a v a i l a b l e f o r a p p l i c a t i o n
of t h i s procedure. Once utilized quality
a
uniform
to
objectively interval
frequencies)
of
the of
where
Thus,
stations
sampled
more
frequently
little.
With
number
reference
of
of
sampling
annual
equality
station.
these
samples
per
13.2
the
(for
it
can
within
a
varies
where which
of
specifying
in a
the is
mean
number
at
water
a
of
fashion sampling
tremendously plot
of
samples
will
quality
log r i v e r
the
flow
the
sampling
each
water
be
of
consistent
half-widths
quality
interval
year,
frequencies
mean
stations
selected
the expected h a l f - w i d t h
expected
Figure
the confidence
is
basin-wide
water
than
to
criterion
For example,
approach c a n be a p p l i e d
specifying
half-width
frequency
distribute
m o n i t o r i n g network.
confidence by
sampling
be
varies expected
versus
collected
at
the each
s t a t i o n w i t h i n the r i v e r b a s i n f o r a g i v e n R a r e determined b y d r a w i n g a horizontal abscissa curve.
line axis
through below
Figure
13.2
and
R
the
may
reading
intersections also
the
on
be used
number
the
i n an
of
samples
horizontal
line
i t e r a t i v e fashion
on
with to
the each
specify
s a m p l i n g frequencies a t each s t a t i o n when a t o t a l number o f samples from the b a s i n
i s specified.
For example,
collected a n d analyzed, horizontally;
a
v a l u e of
the number of
if
R
only
samples s p e c i f i e d
curves a r e summed a n d compared
to
N
samples
i s assumed
N.
If
the
by
and the
sum
a
per
year
line
is
were drawn
i n t e r s e c t i o n of
were not e q u a l
the to N
then another estimate of R would be made u n t i l the sum of a l l the samples i s equal to N. I t should be noted t h a t the expected h a l f - w i d t h o f the a n n u a l mean i s not the o n l y s t a t i s t i c
that
the expected h a l f - w i d t h a n d may
can
be used
to
specify
s a m p l i n g frequencies;
d i v i d e d b y the mean i s a measure o f r e l a t i v e e r r o r
be more a p p r o p r i a t e
when
assigning
sampling
frequencies
in
a
b a s i n where water q u a l i t y v a r i e s tremendously from r i v e r to r i v e r . When developing s a m p l i n g frequencies, important
cycles
concentrations,
which
can
have
one must keep i n m i n d two v e r y
immense
impact
on
the d i u r n a l c y c l e a n d the weekly cycle.
d i u r n a l cycle (which i s a
f u n c t i o n of
the r o t a t i o n
e l i m i n a t e d b y s a m p l i n g in e q u a l time i n t e r v a l s f o r
of a
water
The effect the e a r t h )
24-hour
quality of can
period
the be and
215 the effect of t h e weekly c y c l e ( w h i c h i s a f u n c t i o n of mans' be eliminated be m u l t i p l e s
by specifying of
seven,
that
and
sampling
occasional
i n t e r v a l s for a
sampling
on
a c t i v i t y ) can
network
weekends
cannot
would
be
necessary.
in terms of v a r i a b l e s
Perhaps the major impact between network design to
monitored,
be
operational
sampling
monitoring
consequently,
location,
functions
ultimate
v a l u e of
sampling program that
is
and
the
sampling
the
in
area
monitoring
frequency
of
data
network
and
the
analysis
and,
information.
Any
i s to generate conclusive r e s u l t s from o b s e r v i n g
stochastic process ( w a t e r q u a l i t y concentrations) must be well s t a t i s t i c a l l y designed.
S t a t i s t i c a l l y designed
implies
p l a n n e d ( i n p r o p e r locations and numbers) so t h a t
that
a
planned and
the
sampling
the s t a t i s t i c a l
techniques chosen w i l l be a b l e to y i e l d q u a n t i t a t i v e information.
is
analysis Thus,
the
d a t a a n a l y s i s techniques ( l e v e l and t y p e of s t a t i s t i c s ) to be used must be defined
in
order
to
know
how
to
compute
proper
sampling
frequencies,
locations, etc.
D ISCUSS ION The above section has pointed out many problems due to not d e s i g n i n g a m o n i t o r i n g system that
all
accuracy. on
aspects
in a
of
For example,
nonrepresentative,
excessive segment
.
a
accuracy
context.
Perhaps
program
i n one
sample d a t a . segment
The
compared
the major
should
i t would not be wise to
grab
I n a s i m i l a r manner, sophisticated
systems
monitoring
match
use
time
system to
concern
in
terms
series
would
be
the accuracy
analysis providing another
in
i t may be u n r e a l i s t i c to encourage use of
sample collection
and
laboratory
is of
a n a l y s i s techniques
more
if
the
d a t a i s not to receive a thorough s t a t i s t i c a l a n a l y s i s . It
i s difficult
to
test
hypotheses,
make decisions
flow
weighted,
several
times
a
year,
from
and
i n i t i a t e action
in the daytime a n d not
u s i n g water q u a l i t y d a t a which a r e collected o n l y
locations
which
are
not
completely mixed a n d u s i n g l a b analyses procedures which may h a v e more variation
in
their
results
when
analyzing
the
same
sample
than
the
ambiant v a r i a t i o n of the water q u a l i t y v a r i a b l e in the r i v e r . Perhaps an even l a r g e r concern to those in m o n i t o r i n g network i s the
use of
water
quality
T h i s lowers the v a l u e of a n y t h a t of spot checks. standards
would
standards information
that
generally
ignore
design
statistics.
from a compliance v i e w p o i n t ,
I n c o r p o r a t i n g water q u a l i t y means a n d v a r i a t i o n
greatly
facilitate
incorporating
more
statistics
to into into
216 m o n i t o r i n g . T h i s would h a v e t h e effect of t y i n g network design to d a t a use in a much more concrete,
a l s o encourage use of would
be
a
s t a t i s t i c a l manner t h a n i s now possible.
the
statistical
system
thread
approach moving
to
network
through
the
design entire
I t would as
there
monitoring
operat ion.
REFERENCES Lettenmaier, D.P., 1975. Design of M o n i t o r i n g Systems f o r Detection of Trends i n Stream Q u a l i t y . Technical Report No. 39, Charles W. H a r r i s H y d r a u l i c s L a b o r a t o r y , U n i v e r s i t y of Washington, Seattle. L o f t i s , J.C. a n d Ward, R.C., 1978. S t a t i s t i c a l Tradeoffs i n M o n i t o r i n g Network Design, presented a t AWRA Symposium Establishment of Water Q u a l i t y M o n i t o r i n g Programs. San Francisco, C a l i f o r n i a . a n d Orlob, G.T., 1967. Problems of S e t t i n g S t a n d a r d s o f Pomeroy, R.D. S u r v e i l l a n c e f o r Water Q u a l i t y Control. C a l i f o r n i a State Water Q u a l i t y Control Board P u b l i c a t i o n No. 65, Sacramento, C a l i f o r n i a . 1968. Stochastic A n a l y s i s of D a i l y R i v e r Flows. Journal o f Quimpo, R.G., H y d r a u l i c s , ASCE. 94(HY1) p43-47. A d r i a n , D.D. a n d Joyce, J.M., 1977. M i x i n g L e n g t h f o r Sanders, T.G., Representative Water Q u a l i t y Sampling. Journal Water P o l l u t i o n Control Federation. 49 p2467-2478. T.G. a n d Ward, R.C., 1978. R e l a t i n g Stream Standards to Sanders. Regulatory Water Q u a l i t y M o n i t o r i n g Practices. Presented a t the AWRA Symposium “Establishment of Water Q u a l i t y M o n i t o r i n g Programs, San Francisco, Ca I i f o r n i a . and Adrian, D.D., 1978. Sampling Frequency f o r R i v e r Sanders, T.G. Q u a l i t y M o n i t o r i n g . Water Resources Research. 1 4 ( 4 ) p 569-576. Ward, R.L. L o f t i s , J.G. Steel, T.D, Adrian, D.D. and Sanders, T.G., 1986. Design of Networks f o r M o n i t o r i n g Water Q u a l i t y , Yevjevich, V., 2nd E d i t i o n , Water Resources P u b l i c a t i o n s , Colorado. Sharp, W.E., 1973. A T o p o l o g i c a l l y Optimum R i v e r Sampling P l a n f o r South C a r o l i n a . Water Resources Research I n s t i t u t e Report No. 36, Clemson U n i v e r s i t y , Clemson , South Carol i n a . Neilsen, K.S. a n d Bundgaard-Nielsen, M., 1976. Design of Ward, R.C., M o n i t o r i n g Systems f o r Water Q u a l i t y Management. C o n t r i b u t i o n f o r the Water Q u a l i t y I n s t i t u t e , Danish Academy of Technical Science, No. 3, Horshdm, Denmark.
WATER
QUALITY MON I TOR I NG NETWORKS i Y
Colorado State U ive
b y Thomas G. Sanders,
NECESS I T Y FOR NETWORKS Environmental
legislation
been responsible f o r recent streams.
Such m o n i t o r i n g
and
general
water
quality
awareness
have
increased m o n i t o r i n g a n d s a m p l i n g of water and
testing
can
be expensive
and
a
in
scientific
approach to m i n i m i z i n g costs w h i l s t m a x i m i z i n g b e n e f i t s i s d e s i r a b l e . The
assumption
trends
in
water
that
a
quality,
measure ambient
water
monitoring
actively
guide
implemented,
in
government's
however,
feasibi I i t y
obtaining
conclusive
compromises a n d
compliance etc.,
is
with
water
water
legal
the
view
being
is
the
of
more
which
to
When from
a
in
involved
resources force
of
for
water
efforts.
viewed
available
and
generated
problems
the consequences
detect
legislation
management
is,
can
standards,
into
The
monitoring
That
information w i t h measures,
stream
information
quality
quality
network
incorporated
conclusive
stand-point.
half
monitoring
the U n i t e d States.
envisages
technical
quality
check
quality,
water q u a l i t y management qua1 i t y
water
many
a r e often
not
f u l l y understood. Monitoring conducted
over
necessarily Simply
performed large
hydrologic
collecting
problem; cases, samples
or
ultimate
of
geographic
in
i n fact,
thought types
use
government
is
that
of
data
the
data.
(defined
covering
such
given
agencies
areas
boundaries)
samples
so major,
little
by
a
by
the
analysis
many
political
often
i t becomes a n end to
in
in
techniques
Consequently,
the
to
be
majority
a
used of
major
In many
itself. of
not
streams.
becomes
representativeness
cases,
and
k i lometres of
many
situation
is,
the
or
water
even
the
resources
are
devoted to c o l l e c t i n g d a t a as i t i s the most immediate problem. By
using
most
resources
to
physically
collect
water
resources a r e l e f t to consider the representativeness of a n d space,
d a t a a n a l y s i s o r d a t a use.
m o n i t o r i n g system system
should
be
should
therefore
examined
and
samples,
the sample
little i n time
A b a l a n c e d ( c o l l e c t i o n versus
be developed designed
so
use)
the e n t i r e m o n i t o r i n g
simultaneously
(a
systems
the
system
approach). The purpose of
t h i s chapter
i s to
review
monitoring
and
then d e l i n e a t e the impacts t h a t such a systems a p p r o a c h of m o n i t o r i n g w i l l h a v e on network design b y c o n s i d e r i n g the w a t e r q u a l i t y
v a r i a b l e s to
be
205 monitored,
the sampling location a n d s a m p l i n g frequency.
MONITORING SYSTEM FRAMEWORK
Before
a
monitoring
network
can
be
m o n i t o r i n g program should be delineated, I n addition,
the decisions
designed
the
goals
of
the
and specific objectives applied.
to be made based
upon
information
network and the subsequent actions should also be well
from
the
developed p r i o r to
the collection o r a s i n g l e b i t of data. The a c t u a l
operation
of
a m o n i t o r i n g system can
be
categorized
into
f i v e major functions:
1.
Sample Collection
2.
Laboratory Analysis
3.
Data H a n d l i n g
4.
Data A n a l y s i s
5.
I nformation U t i I i z a t i o n These f i v e functions serve as
quality
conditions
of
water
management
agency
approvals,
regulations,
qua1 i t y . effects
Without of
those
a
the feedback
quality
loop from
management
i s c o n s t a n t l y m a k i n g decisions pollution
monitoring
decisions,
abatement,
feedback
the
loop
(e.g.
etc.)
past
water
making.
r e l a t i v e to
that
accurately
management's
in-stream
decision
affect
and
site
water
documenting
success
A
the
future
direction are uncertain. M o n i t o r i n g network design operational collection
i s an o v e r r i d i n g a c t i v i t y
f u n c t i o n s l i s t e d above) (e.g.
location
that
a n d frequency)
should c a r e f u l l y with
used to o b t a i n the i n f o r m a t i o n r e q u i r e d a n d making.
Thus,
the
type
actually
( c o v e r i n g the f i v e i n t e g r a t e sample of
data
utilized
analysis
in decision
the design of water q u a l i t y m o n i t o r i n g networks must
i n t o account the decision m a k i n g process,
take
the t y p e and level o f s t a t i s t i c a l
a n a l y s i s a p p l i e d to the d a t a , a n d u l t i m a t e use of the d a t a collected. FACTORS I N NETWORK DESIGN M o n i t o r i n g network
design,
guides m o n i t o r i n g operations,
as a p l a n n i n g / d e s i g n can
i t s e l f be broken
componen ts:
1.
Selection of Water Q u a l i t y V a r i a b l e s to Monitor
2.
Sampling Station Location
type function
down
which
i n t o three m a j o r
206
3.
Sampling Frequency The
term
water
quality
variable
is
used
instead
of
water
quality
parameter because water q u a l i t y i s a random v a r i a b l e a n d c a n be d e f i n e d by
statistical
addition,
parameters
the term
deterministic
parameter
equations
a s the mean a n d
such or
is
most
models
often
and
standard
used
to
can
lead
it
deviation.
define
In
constants confusion
to
of by
i d e n t i f y i n g i t a s a random v a r i a b l e . the
monitoring
system's o p e r a t i o n a l f u n c t i o n s I i s t e d p r e v i o u s l y a n d v i c e versa.
Each
of
these
factors
The degree
of impact, however,
in
network
design
effects
all
depends upon the purpose a n d g o a l s of
the m o n i t o r i n g
system. SELECT ION OF WATER QUALITY VARIABLES TO MEASURE
to
The selection of the water q u a l i t y
v a r i a b l e to be sampled w i l l
a
of
l a r g e extent
background developing network
frame
the of
its
objectives reference
the o b j e c t i v e s
has
stndards, for
or
on
of
primary
the
of
the
sampling
the
individuals
monitoring
objective
to
network
network.
monitor
the
responsible
for
When
a
compliance
sampl i n g
with
stream
the v a r i a b l e s sampled a r e the ones s p e c i f i e d i n the l e g i s l a t i o n ,
example,
dissolved
(DO).
oxygen
DO
is
sampled
because
s t a n d a r d s specify a minimum l e v e l which should not be v i o l a t e d . s t a n d a r d l e g i s l a t i o n were those r e l a t e d to water s u p p l y , biochemical oxygen demand a n d dissolved solids,
(BOD),
stream
Dissolved
i m p o r t a n t a n d i n c l u d e d in stream
oxygen a n d o t h e r v a r i a b l e s deemed most
quality
depend
and
temperature,
col iform b a c t e r i a ,
turbidity,
and
suspended
because most i n d i v i d u a l s e n t e r i n g the f i e l d o f water
management d u r i n g
the
last
few
decades
have
a
background
in
s a n i t a r y engineering. Since i n d i v i d u a l s o t h e r t h a n besides s a n i t a r y became interested i n water q u a l i t y , which
should
be
sampled
( e n v i r o n m e n t a l ) engineers
the number of water
routinely
has
increased.
quality This
variables
compounding
syndrome cannot a n d should not be the major v a r i a b l e selection mode f o r a permanent,
routine
accommodated
in
sampling
the
p o p u l a r i t y of synoptic
much
program,
discussed
but
instead
synoptic
can
surveys.
be
The
easily
increasing
s u r v e y s w i t h s a m p l i n g agencies i s p r o b a b l y
due to
the f a c t t h a t the s u r v e y s a r e in fact a n a p p l i c a t i o n of a systems a p p r o a c h to
water
programs, sampling
quality
monitoring.
the objectives, frequency,
the
Unlike
the
permanent,
the use of the d a t a , variables
to
be
routine
the s a m p l i n g
sampled
as
well
sampling
locations, as
the
the data
207 analysis
procedures
and
decisions
to
be
made
should
be
developed
be
developed
completely before the survey i s undertaken. Both
sampling
independently
location
of
the
and
water
sampling
quality
frequency
variable
to
can
be
analyzed,
location and frequency a r e specified f o r the c o l l e c t i o n of ( t h e analyses a r e made l a t e r ) .
However,
water
monitored.
quality
week
at
a
monitoring
variable
single the
being
point
in
relatively
a
river
stable
For
may
river
the
variables
t h e i r n a t u r a l and/or
considered
when
be
more
temperature, coliform
sampling than
but
once
adequate
may
bacteria
water
delineated.
Network
concentration
qua1 i t y
is
concentration,
the
as
former
be
sample
in
if
opposed
being
a
to
an
result
24-hour
(generally
daily
in
space
In
several
period,
while
the daytime,
in a be to
should
be
(flow
weighted)
grab
samples the
can
addition
units
mean
instantaneous
of
for
hardly
be s p e c i f i e d so
time a n d
respective
a
a
concentrations.
should
network.
their
differs
measurements spaced d u r i n g a single
variation
monitoring
variables,
design
needed
the
to be monitored
man-made
designing
considering
only a
example,
before a water q u a l i t y m o n i t o r i n g network can be designed
systematic fashion, that
both
both c r i t e r i a a r e affected b y the
adequate for m o n i t o r i n g r a p i d l y v a r y i n g Therefore,
as
the water sample
sample
with
latter
flow
comprises a.m.
between 8.00
and
4.30 p.m.1. In
reality,
the
specification
of
the
water
quality
variable
however, water
to
be
In p r a c t i c e ,
monitored p r i o r to i n i t i a t i n g network design would be ideal.
network design i s specified a n d one must know o r determine what
quality
variables
can
be
accurately
monitored
with
the
existing
a
water’
network.
SAMPL I NG STAT ION LOCAT ION The
location
of
m o n i t o r i n g network design,
a
permanent
i s probably
b u t a l l too often
never
comprises lead i n many cases r i v e r g a u g i n g stations. the
gauging
sampled
is
collectors
station not
and
follow
when
most
properly
is
truly
addressed.
representative generally
of
the
water
the
in
aspect
of
quality
the
Expediency
network a n d cost
near existing
Whether the s i n g l e g r a b sample from the b r i d g e o r but
users
station
critical
to s a m p l i n g from b r i d g e s o r
known,
e s t i m a t i n g discharge, indicate exactly
sampling
the
is
quality
of
the
assumed data.
measuring
discharge.
water
quality
However, variable
be
Using
measurement anywhere i n the river
water to
lateral
t h i s does
mass
being
by
both
the
river
stage
for
transect not
would
necessarily
concentrations.
In
fact
208
F i g , 13.1
Macrolocation of Sampling Stations W i t h i n a R i v e r Basin Using the Percent Areal Coverage a s the C r i t e r i a S p e c i f y i n g Locat ion
209 research
indicates
the
opposite,
that
will
rarely
a
single
sample
be
i n d i c a t i v e of the average water q u a l i t y i n a r i v e r cross section. Sampling
locations
for
a
c l a s s i f i e d i n t o two levels of
permanent design:
water
quality
network
former
b e i n g a f u n c t i o n o f the specific objectives o f the network
latter
being
independent
of
can
be
macrolocation a n d microlocation,
the
objectives
but
a
the
and
the
of
the
function
representativeness of the water sample to be collected. The political etc.
macrolocation
within
boundaries,
a r e a s of
Macrolocation can
a
river
basin
usually
major p o l l u t i o n
be specified,
coverage u s i n g b a s i n c e n t r o i d s
a s well,
(Sanders et
is
loads,
determined
population
a c c o r d i n g to percent
1986).
al,
This
locates sampling p o i n t s in a systematic f a s h i o n m a x i m i z i n g the e n t i r e b a s i n w i t h a few s t r a t e g i c a l l y an
example
of
locating
sampling
using
areal
methodology
information of F i g u r e 13.1
located stations.
stations
by
centres,
basin
centroids
is and
sub-basin centroids w i t h percent a r e a l coverage a s the c r i t e r i a . The procedure f o r l o c a t i n g sampling s t a t i o n s i s d e r i v e d b y d e t e r m i n i n g the c e n t r o i d o f a r i v e r system. i s a stream
without
defined
i n t e r i o r stream r e s u l t i n g from
value
equal
to
the
i s given
intersection
of
the v a l u e o f two e x t e r i o r
(this
one;
an
tributaries
Continuing downstream i n the same manner,
would have a v a l u e of two. streams intersect,
Each c o n t r i b u t i n g e x t e r i o r t r i b u t a r y
tributaries)
as
the r e s u l t a n t downstream s t r e t c h of r i v e r would h a v e a the
sum
of
the
values
of
the
preceeding
intersecting
stream. At the mouth of the r i v e r , the v a l u e o f the f i n a l r i v e r section w i l l be equal to the number o f c o n t r i b u t i n g e x t e r i o r t r i b u t a r i e s ,
22 in F i g u r e
13.1.
by
D i v i d i n g the
v a l u e of
the f i n a l
v a l u e of the c e n t r o i d of the b a s i n ,
s t r e t c h of
1 1 i s calculated.
h a v i n g a v a l u e equal to t h a t of the c e n t r o i d sections and
i s the
location of
the
the
river
r i v e r basin, of
I n many
sampling station
cases,
when
with
When
this
occurs,
closest to the c e n t r o i d i s chosen.
the
stream
highest
the
initial
river
basin
centroid.
segment
having
the two equal The
two
order
the mouth
t h i s procedure to
The n e x t o r d e r o f sampling
determined b y f i n d i n g the c e n t r o i d v a l u e of a n d below
applying
into
there i s u s u a l l y not a stream h a v i n g a v a l u e e q u a l to
the centroid.
the
The section of r i v e r
d i v i d e s the b a s i n
( t h e assumption i s made t h a t there e x i s t s a s a m p l i n g s t a t i o n a t of the r i v e r b a s i n ) .
two,
a
a
that value
locations
is
sections above
procedure
is
continued
u n t i l a percentage of a r e a l coverage i s a t t a i n e d . The percentage of area coverage specified b y the m o n i t o r i n g agency defined as the number of
sampling
the
this
basin.
sampling
Intrinsic
in
station hierarchy
stations d i v i d e d b y
objective
that
procedure
o r d e r s the
is
importance
is
the m a g n i t u d e of the of
concept each
of
a
sampling
210 station
in the b a s i n
1973). T h i s p r o v i d e s a
(Sharp,
r e a l i s t i c methodology
i n which a r a t i o n a l implementation progam c a n proceed: stations
(highest
available,
order)
additional
are
built
first
and
as
the most
the
important
resources
become
As each succeeding h i e r a r c h y
s t a t i o n s can be b u i l t .
of s t a t i o n s a r e e s t a b l i s h e d the percentage of a r e a l coverage i s increased. Having
established
microlocation
the
specifies
macrolocations
the
river
within
reach
to
a
be
river sampled
microlocation specifies the p o i n t i n the r e a c h to be sampled.
basin,
the
while
the
This point
is
t h e location of a zone in the r i v e r r e a c h where complete m i x i n g e x i s t s a n d
in o r d e r to o b t a i n a
o n l y one sample i s r e q u i r e d from the l a t e r a l transect
(in
representative
space)
sample.
Being
downstream from the nearest o u t f a l l ,
a
function
t h e zone of
of
the
distance
complete m i x i n g can
be
estimated u s i n g v a r i o u s methodologies. Given the assumptions t h a t a p o i n t
source
stream approximates a Gaussian d i s t r i b u t i o n , modelled
using
image
theory,
in a
d i s t a n c e downstream
the
following
straight,
pollutant
a n d t h a t b o u n d a r i e s can equation
u n i f o r m channel
-
-
(J
Y
where
a point
L
Y
be the
source
1977).
2u
(13.1) is
the
from
mixing
source
velocity and D Estimates of D
Y
predict
2oy
distance
D
can
from
p o l l u t a n t to a zone of complete m i x i n g (Sanders et a l . ,
LY
in a
distribution
Y
Y
to
distance farthest
for
complete
lateral
lateral
boundary,
u
mixing,
a y
is
stream
mean
is
i s the l a t e r a l t u r b u l e n t d i f f u s i o n coefficient. can be made u s i n g e q u a t i o n 13.2
= 0.23 du'
(13.2)
where d i s depth of flow u* i s shear v e l o c i t y
g
i s acceleration flow
due to g r a v i t y R i s h y d r a u l i c r a d i u s S i s slope o r t h e h y d r a u l i c g r a d i e n t (Sanders e t al., Unfortunately,
1977). there may not e x i s t
in a g i v e n r i v e r
of complete m i x i n g due i n p a r t to the random n a t u r e of
mixing
distance,
determination of
inapplicability
of
the m i x i n g distance,
the
assumptions
o r more often
river
l e n g t h o r t u r b u l e n c e to assure complete m i x i n g
river
reach.
On
the o t h e r
hand field
reach any
within
in
used
t h a n not,
v e r i f i c a t i o n of
points
the aforementioned not
the
enough
the s p e c i f i e d
a completely
mixed
zone p r i o r to l o c a t i n g a permanent s a m p l i n g s t a t i o n c a n be e a s i l y done b y collecting
m u l t i p l e samples
in the cross
u s i n g a we1 I-known one- o r two-way
section
and analyzing
the
a n a l y s i s of v a r i a n c e techniques.
data
21 1 If
there
sampled,
is
not
a
completely
mixed
zone
the
in
river
reach
to
be
there a r e three a l t e r n a t i v e s :
( 1 ) Sample anyway a t a s i n g l e p o i n t a n d assume i t i s r e p r e s e n t a t i v e ( t h i s i s a general approach adopted t o d a y ) ;
( 2 ) Don't sample the r i v e r reach a t a l l , obtained does not q u a l i t y o f the
represent
sample
because t h e d a t a w h i c h would be
the e x i s t i n g r i v e r
quality,
b u t only
In o t h e r words,
volume collected.
the
the data
is
useless;
( 3 ) Sample a t several p o i n t s in the l a t e r a l transect c o l l e c t i n g a composite mean, which would be r e p r e s e n t a t i v e of the water q u a l i t y
in the r i v e r
a t that p o i n t i n time a n d space.
I f the sample i s not r e p r e s e n t a t i v e of the water mass, sampling
as
presentation
well and
as the
the
mode
realistic
m a k i n g becomes inconsequential.
of
use
data of
analysis,
the
data
interpretation
for
I n s p i t e of t h i s f a c t ,
the frequency of
objective
and
decision
c r i t e r i a to e s t a b l i s h
s t a t i o n locations f o r r e p r e s e n t a t i v e s a m p l i n g h a v e received r e l a t i v e l y
little
a t t e n t i o n from many i n s t i t u t i o n s a n d agencies responsible f o r water q u a l i t y monitoring. SAMPLING FREQUENCY Once sampling
stations
a r e representative
have been
i n space,
located to ensure
sampling
frequency
samples collected
should
be
specified
so
t h a t the samples a r e r e p r e s e n t a t i v e in time. Sampling frequency basin
is
a
very
a t each permanent
important
parameter
sampling station w i t h i n a
which
must
be
considered
design of a water q u a l i t y m o n i t o r i n g network.
A l a r g e p o r t i o n of
o f o p e r a t i n g a m o n i t o r i n g network
r e l a t e d to
sampling.
However,
the
reliability
d e r i v e d from a m o n i t o r i n g network sampling.
Addressing
is directly
this
and
utility
of
river in
the
the costs
the frequency
water
quality
of
data
i s l i k e w i s e r e l a t e d to the frequency of
anomaly
Quimpo
(1968)
summarized
the
s i g n i f i c a n c e of sampling frequency a n d stated t h a t : On the one hand,
b y s a m p l i n g too often,
obtained i s r e d u n d a n t and t h u s expensive, hand,
the i n f o r m a t i o n a n d on the other
sampling too i n f r e q u e n t l y bypasses some i n f o r m a t i o n
necessitating an extended p e r i o d of observation. Significant v i o l a t ion
,
as
sampling
frequency
is
m a i n t a i n i n g e f f I uent standards,
i n ambient water q u a l i t y ,
very
to
detecting
stream
standards
a n d e s t i m a t i n g temporal changes
l i t t l e q u a n t i t a t i v e c r i t e r i a which designate
a p p r o p r i a t e sampling frequencies h a v e been a p p l i e d to the design of water
21 2 quality
monitoring
networks.
many
In
cases,
professional
judgment
cost c o n s t r a i n t s p r o v i d e the b a s i s f o r s a m p l i n g frequencies.
All
frequencies
upon
are
capabilities, only
the
same
at
once-a-month,
practical
means
each
station
once-a-week,
to
implement
etc.
a
frequencies
as
and
1978).
Adrian,
functions
of
the
variable
(Nyquist frequency),
maximum
to
minimum
flow
cyclic
methods
variations
and
(Ward et
possibly
the
considering
the
include
of
the
b a s i n area
water
and
19671,
Orlob,
specifying
of
a
test
measuring
the
confidence
1976; L o f t i s a n d Ward,
al,
water
quality
the r a t i o of
quality
intervention
1978),
1978), and
the number of d a t a p e r y e a r f o r hypotheses (Sanders and Ward, the power
routing
s a m p l i n g frequencies a t each
The
the d r a i n a g e
(Pomeroy
i n t e r v a l o f the a n n u a l mean
although
program
too often,
there do e x i s t many q u a n t i t a t i v e ,
s t a t i s t i c a l l y meaningful procedures to specify (Sanders
based
and
sampl i n g
s t a t i s t i c a l b a c k g r o u n d o f d a t a collectors, station
and
and
(Lettenmaier,
1975).
A l l of the aforementioned procedures can b e a p p l i e d to the design of a water q u a l i t y m o n i t o r i n g network w i t h each r e q u i r i n g a d i f f e r e n t statistical
sophistication
assumptions app I y One of variable
the
.
simplest
(iid)
and
as
approaches
concentrations
distributed
insofar
are
is
data
to assume
random,
determine
the
requirements that
the
independent
number
of
as
well
water
and
samples
level of as
quality
identically
per
year
as
a
f u n c t i o n o f an a l l o w a b l e ( s p e c i f i e d ) confidence i n t e r v a l of the mean a n n u a l concentration analyses of
( t h i s i s analogous to the procedure f o r d e t e r m i n i n g how many a
water
sample
should
be
made
to
determine
a
reasonable
estimate o f the mean water q u a l i t y v a r i a b l e c o n c e n t r a t i o n ) .
[
n =
aizS]
(13.3)
where n i s the number of e q u a l l y is a
constant
number
of
which
samples,
is a
S
is
spaced samples collected p e r y e a r ,
function the
of
the
standard
l e v e l of
deviation
concentrations a n d R i s s p e c i f i e d h a l f - w i d t h
of
significance of
the
water
the confidence
taI2
and
the
quality
interval
of
the a n n u a l mean. Using the same assumption,
t h a t the water
number of samples p e r
year
can
a n a l y s i s procedure as
well.
For
quality
be s p e c i f i e d a s a example,
if
variable i s iid, function
annual
of
means
tested f o r s i g n i f i c a n t changes u s i n g the d i f f e r e n c e in means,
the
the data
were
to
be
then to detect
a n assumed level of change, t h e number of samples c a n be specified.
A
more
sophisticated
procedure,
representing
a
higher
level
of
21 3
0.9
0.8
R vs. Number of Somples per Yeor I 2 3 4 5 6 7 8
0.7
0.6
Wore Conn. at Thompsonville Deerfield Conn. ot Montopue City Millers Conn.ot Vernon
Westfield Conn. ot Turners Falls
R
0.5
0.4
0.3
0.2
0. I
I
10
1
20
I
30
I
40
I
50
Number of Somples per Yeor
Fig 13.2
A p l o t n u m b e r o f s a m p l e s per y e a r of the expected h a l f - w i d t h of t h e c o n f i d e n c e i n t e r v a l of m e a n log f l o w , R , v e r s u s n u m b e r of S a m p l e s for S e v e r a l R i v e r s in t h e C o n n e c t i c u t R i v e r B a s i n
214 statistical
analysis,
may not be i i d ,
would
be
to recognize
b u t h i g h l y dependent,
that
water
seasonal v a r i a t i o n ,
a n d determine s a m p l i n g frequency
variability
water
of
the
quality
p e r i o d i c components h a v e daily
discharge,
data
been
variable
removed.
bases
of
quality
veriables
not i d e n t i c a l l y d i s t r i b u t e d ,
as a f u n c t i o n of
series
after
trend
Unfortunately,
other
than
water
time
having
quality
number, r e l i a b i l i t y a n d l e n g t h a r e g e n e r a l l y
variable
of
the and
mean
sufficient
not a v a i l a b l e f o r a p p l i c a t i o n
of t h i s procedure. Once utilized quality
a
uniform
to
objectively interval
frequencies)
of
the of
where
Thus,
stations
sampled
more
frequently
little.
With
number
reference
of
of
sampling
annual
equality
station.
these
samples
per
13.2
the
(for
it
can
within
a
varies
where which
of
specifying
in a
the is
mean
number
at
water
a
of
fashion sampling
tremendously plot
of
samples
will
quality
log r i v e r
the
flow
the
sampling
each
water
be
of
consistent
half-widths
quality
interval
year,
frequencies
mean
stations
selected
the expected h a l f - w i d t h
expected
Figure
the confidence
is
basin-wide
water
than
to
criterion
For example,
approach c a n be a p p l i e d
specifying
half-width
frequency
distribute
m o n i t o r i n g network.
confidence by
sampling
be
varies expected
versus
collected
at
the each
s t a t i o n w i t h i n the r i v e r b a s i n f o r a g i v e n R a r e determined b y d r a w i n g a horizontal abscissa curve.
line axis
through below
Figure
13.2
and
R
the
may
reading
intersections also
the
on
be used
number
the
i n an
of
samples
horizontal
line
i t e r a t i v e fashion
on
with to
the each
specify
s a m p l i n g frequencies a t each s t a t i o n when a t o t a l number o f samples from the b a s i n
i s specified.
For example,
collected a n d analyzed, horizontally;
a
v a l u e of
the number of
if
R
only
samples s p e c i f i e d
curves a r e summed a n d compared
to
N
samples
i s assumed
N.
If
the
by
and the
sum
a
per
year
line
is
were drawn
i n t e r s e c t i o n of
were not e q u a l
the to N
then another estimate of R would be made u n t i l the sum of a l l the samples i s equal to N. I t should be noted t h a t the expected h a l f - w i d t h o f the a n n u a l mean i s not the o n l y s t a t i s t i c
that
the expected h a l f - w i d t h a n d may
can
be used
to
specify
s a m p l i n g frequencies;
d i v i d e d b y the mean i s a measure o f r e l a t i v e e r r o r
be more a p p r o p r i a t e
when
assigning
sampling
frequencies
in
a
b a s i n where water q u a l i t y v a r i e s tremendously from r i v e r to r i v e r . When developing s a m p l i n g frequencies, important
cycles
concentrations,
which
can
have
one must keep i n m i n d two v e r y
immense
impact
on
the d i u r n a l c y c l e a n d the weekly cycle.
d i u r n a l cycle (which i s a
f u n c t i o n of
the r o t a t i o n
e l i m i n a t e d b y s a m p l i n g in e q u a l time i n t e r v a l s f o r
of a
water
The effect the e a r t h )
24-hour
quality of can
period
the be and
215 the effect of t h e weekly c y c l e ( w h i c h i s a f u n c t i o n of mans' be eliminated be m u l t i p l e s
by specifying of
seven,
that
and
sampling
occasional
i n t e r v a l s for a
sampling
on
a c t i v i t y ) can
network
weekends
cannot
would
be
necessary.
in terms of v a r i a b l e s
Perhaps the major impact between network design to
monitored,
be
operational
sampling
monitoring
consequently,
location,
functions
ultimate
v a l u e of
sampling program that
is
and
the
sampling
the
in
area
monitoring
frequency
of
data
network
and
the
analysis
and,
information.
Any
i s to generate conclusive r e s u l t s from o b s e r v i n g
stochastic process ( w a t e r q u a l i t y concentrations) must be well s t a t i s t i c a l l y designed.
S t a t i s t i c a l l y designed
implies
p l a n n e d ( i n p r o p e r locations and numbers) so t h a t
that
a
planned and
the
sampling
the s t a t i s t i c a l
techniques chosen w i l l be a b l e to y i e l d q u a n t i t a t i v e information.
is
analysis Thus,
the
d a t a a n a l y s i s techniques ( l e v e l and t y p e of s t a t i s t i c s ) to be used must be defined
in
order
to
know
how
to
compute
proper
sampling
frequencies,
locations, etc.
D ISCUSS ION The above section has pointed out many problems due to not d e s i g n i n g a m o n i t o r i n g system that
all
accuracy. on
aspects
in a
of
For example,
nonrepresentative,
excessive segment
.
a
accuracy
context.
Perhaps
program
i n one
sample d a t a . segment
The
compared
the major
should
i t would not be wise to
grab
I n a s i m i l a r manner, sophisticated
systems
monitoring
match
use
time
system to
concern
in
terms
series
would
be
the accuracy
analysis providing another
in
i t may be u n r e a l i s t i c to encourage use of
sample collection
and
laboratory
is of
a n a l y s i s techniques
more
if
the
d a t a i s not to receive a thorough s t a t i s t i c a l a n a l y s i s . It
i s difficult
to
test
hypotheses,
make decisions
flow
weighted,
several
times
a
year,
from
and
i n i t i a t e action
in the daytime a n d not
u s i n g water q u a l i t y d a t a which a r e collected o n l y
locations
which
are
not
completely mixed a n d u s i n g l a b analyses procedures which may h a v e more variation
in
their
results
when
analyzing
the
same
sample
than
the
ambiant v a r i a t i o n of the water q u a l i t y v a r i a b l e in the r i v e r . Perhaps an even l a r g e r concern to those in m o n i t o r i n g network i s the
use of
water
quality
T h i s lowers the v a l u e of a n y t h a t of spot checks. standards
would
standards information
that
generally
ignore
design
statistics.
from a compliance v i e w p o i n t ,
I n c o r p o r a t i n g water q u a l i t y means a n d v a r i a t i o n
greatly
facilitate
incorporating
more
statistics
to into into
216 m o n i t o r i n g . T h i s would h a v e t h e effect of t y i n g network design to d a t a use in a much more concrete,
a l s o encourage use of would
be
a
s t a t i s t i c a l manner t h a n i s now possible.
the
statistical
system
thread
approach moving
to
network
through
the
design entire
I t would as
there
monitoring
operat ion.
REFERENCES Lettenmaier, D.P., 1975. Design of M o n i t o r i n g Systems f o r Detection of Trends i n Stream Q u a l i t y . Technical Report No. 39, Charles W. H a r r i s H y d r a u l i c s L a b o r a t o r y , U n i v e r s i t y of Washington, Seattle. L o f t i s , J.C. a n d Ward, R.C., 1978. S t a t i s t i c a l Tradeoffs i n M o n i t o r i n g Network Design, presented a t AWRA Symposium Establishment of Water Q u a l i t y M o n i t o r i n g Programs. San Francisco, C a l i f o r n i a . a n d Orlob, G.T., 1967. Problems of S e t t i n g S t a n d a r d s o f Pomeroy, R.D. S u r v e i l l a n c e f o r Water Q u a l i t y Control. C a l i f o r n i a State Water Q u a l i t y Control Board P u b l i c a t i o n No. 65, Sacramento, C a l i f o r n i a . 1968. Stochastic A n a l y s i s of D a i l y R i v e r Flows. Journal o f Quimpo, R.G., H y d r a u l i c s , ASCE. 94(HY1) p43-47. A d r i a n , D.D. a n d Joyce, J.M., 1977. M i x i n g L e n g t h f o r Sanders, T.G., Representative Water Q u a l i t y Sampling. Journal Water P o l l u t i o n Control Federation. 49 p2467-2478. T.G. a n d Ward, R.C., 1978. R e l a t i n g Stream Standards to Sanders. Regulatory Water Q u a l i t y M o n i t o r i n g Practices. Presented a t the AWRA Symposium “Establishment of Water Q u a l i t y M o n i t o r i n g Programs, San Francisco, Ca I i f o r n i a . and Adrian, D.D., 1978. Sampling Frequency f o r R i v e r Sanders, T.G. Q u a l i t y M o n i t o r i n g . Water Resources Research. 1 4 ( 4 ) p 569-576. Ward, R.L. L o f t i s , J.G. Steel, T.D, Adrian, D.D. and Sanders, T.G., 1986. Design of Networks f o r M o n i t o r i n g Water Q u a l i t y , Yevjevich, V., 2nd E d i t i o n , Water Resources P u b l i c a t i o n s , Colorado. Sharp, W.E., 1973. A T o p o l o g i c a l l y Optimum R i v e r Sampling P l a n f o r South C a r o l i n a . Water Resources Research I n s t i t u t e Report No. 36, Clemson U n i v e r s i t y , Clemson , South Carol i n a . Neilsen, K.S. a n d Bundgaard-Nielsen, M., 1976. Design of Ward, R.C., M o n i t o r i n g Systems f o r Water Q u a l i t y Management. C o n t r i b u t i o n f o r the Water Q u a l i t y I n s t i t u t e , Danish Academy of Technical Science, No. 3, Horshdm, Denmark.