Land Loss Along the Atlantic Coast

Identification

1.	Description

This regional feature measures the net area of undeveloped coastal land that has converted to open
water since 1996, in approximately five-year increments (lustrums). Separate data series are provided
for the net conversion of dry land to water, nontidal palustrine wetlands to water, and tidal wetland to
water. The net conversion of land to open water is the sum of these three measures.

The submergence of coastal land is the most fundamental impact of rising sea level. Nevertheless,
factors other than rising sea level can convert land to water. Conversion of dry land to wetland can also
result from coastal submergence, but such conversions are not included in this regional feature.

Components of this regional feature include:

•	Cumulative land area converted to open water, by region (Mid-Atlantic and Southeast)

(Figure 1)

•	Cumulative undeveloped land area converted to open water, by type of land lost (dry land, tidal
wetland, non-tidal wetland) (Figure 2)

2.	Revision History

May 2014: Feature published.

Data Sources

3. Data Sources

The regional feature is based on changes in land cover as mapped by the National Oceanic and
Atmospheric Administration's (NOAA's) Coastal Change Analysis Program (C-CAP). This program
produces a nationally standardized database of land cover and land change information for the coastal
regions of the United States. C-CAP provides inventories of coastal intertidal areas, wetlands, and
adjacent uplands with the goal of monitoring these habitats by updating the land cover maps every five
years (see: https://coast.noaa.gov/digitalcoast/tools/lca). For background information about C-CAP, see
Dobson et al. (1995).1

C-CAP has coverage for 1996, 2001, 2006, and 2011, making it possible for this feature to provide
estimates of change for three lustrums. This data set is derived primarily from the data provided by the
Landsat satellites, which have collected images of the Earth's surface since 1972.

1 Dobson et al. (1995) provide extensive details on the original conceptualization of the C-CAP data set, but many
of the details in that report do not accurately describe C-CAP as it exists today.

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C-CAP is a key contributor to the federal government's Multi-Resolution Land Characteristics Consortium
(MRLC), a group of federal agencies dedicated to providing digital land cover data and related
information for the nation (Homer et al., 2007). The signature product of that effort is the National Land
Cover Database (NLCD), which is the federal government's primary data set depicting land use and land
cover in the contiguous United States. For the years 2001, 2006, and 2011, C-CAP is the source for the
NLCD within the coastal zone (Vogelmann et al., 2001; Homer et al., 2007; Fry et al., 2011; Xian et al.,
2011). C-CAP also has coverage for 1996.2

4. Data Availability

The C-CAP data set is available for the contiguous United States for the years 1996, 2001, 2006, and
2011 on NOAA's website at:

https://coast.noaa.gov/dataregistry/search/collection/info/ccapregional?redirect=301ocm. This site
provides downloadable data files, an online viewer tool, and metadata.

Methods

5. Data Collection

This regional feature is based on the C-CAP data set. Creation of the data involves remote sensing,
interpretation, and change analysis.

Remote Sensing

C-CAP is derived from the data provided by a series of Landsat satellites, which have collected imagery
of the Earth's surface since 1972. Landsat is jointly managed by the U.S. Geological Survey (USGS) and
the National Aeronautics and Space Administration (NASA).

As Irish (2000) explains:

The mission of the Landsat Program is to provide repetitive acquisition of high resolution
multispectral data of the Earth's surface on a global basis. Landsat represents the only source of
global, calibrated, high spatial resolution measurements of the Earth's surface that can be
compared to previous data records. The data from the Landsat spacecraft constitute the longest
record of the Earth's continental surfaces as seen from space. It is a record unmatched in
quality, detail, coverage, and value. (Irish, 2000: p.2)

The Landsat satellites have had similar orbital characteristics. For example, Landsat 7 and Landsat 8 orbit
the earth 14.5 times each day, in near-polar orbits. The orbit maintains the same position relative to the
sun, so as the Earth rotates, each orbital pass collects imagery to the west of the previous orbit—about
1,600 miles to the west at the equator. The "sun-synchronous" orbit means that each pass takes place
between about 9:00 a.m. and 10:30 a.m., depending on latitude. Each pass can collect imagery along a
path that is approximately 120 miles wide, leaving gaps between successive passes. The gaps are filled

2 Before 2001, C-CAP and the NLCD diverge. The NLCD's first (and only other) year of coverage was 1992
(Vogelmann et al., 2001). The NLCD's procedure for interpretation changed for subsequent years.

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during the following days, because each day's orbits are approximately 100 miles west of the previous
day's orbits (at the equator). It takes 16 days to complete the entire pattern.

The Landsat data provide multispectral imagery. That imagery is somewhat analogous to an electronic
picture file: for each pixel in a picture, a digital camera measures the intensity of red, blue, and yellow
light and stores these data in a file. Similarly, Landsat measures the intensity of light from different
portions of the electromagnetic spectrum for each pixel, including data from both the visible and
infrared wavelengths. Landsat imagery has a pixel size of approximately 30 x 30 meters.

For more information about the Landsat program, see: http://landsat.gsfc.nasa.gov/ and the resources
cited therein.

Interpretation

Just as people can detect most (but not all) of what they see based on the colors their eyes perceive,
geospatial analysts are able to detect whether the Earth's surface in a given 30 x 30 meter pixel is open
water, vegetated wetlands, forest, grassland, bare intertidal lands (e.g., beaches and mudflats), or
developed, based on the visible and infrared energy coming from a given pixel:

•	Beach sand strongly reflects in all wavelengths.

•	Clear, deep water strongly absorbs in all wavelengths.

•	Sediment-laden water reflects visible wavelengths more than clear water, but reflects infrared
wavelengths similarly to clear water.

•	Vegetation strongly absorbs visible wavelengths and strongly reflects infrared.

•	Marshes can be distinguished from dry land because the wet marsh soils absorb more light than
the soil surface of the adjacent dry lands.

The classification of pixels based on the light emitted does not identify the land cover class everywhere.
For example, tidal wetlands and sloped dry land on the southeastern side of an estuary might be difficult
to distinguish with only remote sensing data: pixels may appear darker either because the land absorbs
more energy due to wet soil conditions or because it is sloped toward the northwest and thus receives
less light in the morning than would the identical land cover on flat ground—and it might even be in a
shadow. The geospatial analysts who create the data generally obtain other information. For example:

•	Information about land slopes and terrain can distinguish whether the land is sloped or flat.

•	Data from the U.S. Fish and Wildlife Service's National Wetlands Inventory (NWI) also help
distinguish dry land from wetlands and distinguish wetland types.

•	Information on soil drainage characteristics is also useful in identifying wetland areas—for
example, data from the U.S. Department of Agriculture's National Cooperative Soil Survey:
http://websoilsurvev.sc.egov.usda.gov/App/HomePage.htm.

MRLC has developed a standardized approach for using remote sensing imagery to classify land cover
(Homer et al., 2007). The C-CAP data set divides the land surface into 24 categories (NOAA, undated)
which follow the MRLC classes, except where C-CAP needs more detail. Table TD-1 shows the

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relationship between C-CAP and NLCD data categories. C-CAP uses the Anderson et al. (1976) Level 2
classification system for dry land.

Table TD-1. Relationship Between C-CAP Land Cover Categories and Other Classification Systems

Anderson Level 1

NLCD category

C-CAP category3

Urban or Built-up Land (1)

Developed, High Intensity (24)

High Intensity Developed (2)

Developed, Medium Intensity (23)

Medium Intensity Developed (3)

Developed, Low Intensity (22)

Low Intensity Developed (4)

Developed, Open Space (21)

Open Space Developed (5)

Agricultural Land (2)

Cultivated Crops (82)

Cultivated Land (6)

Pasture/Hay (81)

Pasture/Hay (7)

Rangeland (3)

Grassland/Herbaceous (71)

Grassland (8)

Scrub/Shrub (52)

Scrub Shrub (12)

Forest(4)

Deciduous Forest (41)

Deciduous Forest (9)

Evergreen Forest (42)

Evergreen Forest (10)

Mixed Forest (43)

Mixed Forest (11)

Wetlands (6)

Woody Wetlands (90)

Palustrine Forested Wetlands (13)

Palustrine Scrub Shrub Wetlands (14)

Estuarine Forested Wetlands (16)

Estuarine Scrub Shrub Wetlands (17)

Emergent Herbaceous Wetlands (95)

Palustrine Emergent Wetlands (15)

Estuarine Emergent Wetlands (18)

Open Water (5)

Open Water (11)

Open Water (21)

Palustrine Aquatic Bed (22)

Estuarine Aquatic Bed (23)

Barren Land (7)

Barren Land (31)

Unconsolidated Shore (19)b

Barren Land (20)

Tundra (8)

Tundra (24)

Perennial Ice/Snow (9)

Perennial Ice/Snow (12)

Perennial Ice/Snow (25)

a Category 1 is land that could not be otherwise classified, and does not apply to any locations along the

Atlantic coast in the C-CAP data set.
bThe Unconsolidated Shore class refers to lands below the daily high water mark. Dry beaches, unvegetated

sand spits, and similar areas are classified as Barren Land.

Source: NOAA: https://coast.noaa.gov/dataregistrv/search/collection

For wetlands, C-CAP uses the more detailed categories from Cowardin et al. (1979), which are also used
by the NWI. C-CAP uses NWI data to distinguish estuarine from freshwater wetlands. The NWI maps by
themselves are insufficient for coastal change, because they are updated so infrequently that digital
maps are only available for one or two years, which vary from state to state.3 Nevertheless, the NWI

3 Along the portion of the Atlantic Coast covered by this feature, NWI maps have been updated since the year
2000 for only five states: New York (2004), Delaware (2007), North Carolina (2010), Georgia (2004-2007), and
Florida south of Volusia County (2006-2010). See "Wetlands Mapper" in U.S. FWS (undated).

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maps are useful for identifying the wetland class that corresponds to a given spectral signature at a
given location.

Even though Landsat provides an image every 16 days, the C-CAP data are intended to represent land
cover for a given year, based on data collected throughout that year—and if necessary, the preceding
year. Interpretation of the Landsat data to create land cover data may require examination of many
Landsat images for each location simply to find one or two that are useful. For some locations, no
available imagery from a given year shows the land cover, so NOAA uses the preceding year.
Distinguishing dry land and some tidal wetlands from open water requires obtaining images close to low
tide. That rules out the majority of images, which are taken when the water is higher than at low tide.
During winter, ice and snow cover can prevent a correct interpretation of whether a pixel is even open
water or dry land, let alone the type of land. Because some types of vegetation become green sooner
than others, distinguishing among those types of land cover may require imagery from a very specific
time in the spring. Even when the tides and ground surfaces are perfect for measuring land cover, clouds
may obscure the image on the morning that the satellite passes.

C-CAP's five-year increment represents a balance between the cost of data interpretation and the
benefits of more observations.

Change Analysis

Most of the climate change indicators in this report depict change over time based on data that are
measured in the same way continuously, daily, or at least once a year. While the same instruments
might be used from year to year, a different measurement is taken each year, or a different annual
measurement is derived from many measurements taken throughout the year. In theory, the C-CAP
data could be created by following the same process once every five years, completely reinterpreting
the data each time. C-CAP uses a different procedure, though, as NOAA
(https://coast.noaa.gov/dataregistry/search/collection) explains:

•	Change detection analysis compares the two dates of imagery to identify the areas that have
likely changed during this time frame. These areas are then classified through a combination of
models, use of ancillary data, and manual edits.... The classified land cover for these areas of
change is then superimposed over the land cover from the original date of analysis, to create a
new wall-to-wall classification for the second time period.

•	Many of the areas that are identified as potentially changed in the change detection and
masking may be changes that do not result in a change in class. Agricultural field rotation or
forest stand thinning are two examples.

•	Remapping only areas that contain change leads to greater efficiency and more consistent data
through time than would procedures that remap the full land cover for an area for each time
period. By looking only at areas that have changed, we remove any difference that could result
from differences in interpretation. This method also reduces cost, since only a small percentage
of the total area must be classified in the change product (i.e., typically less than 20% of any
area changes in a five-year period).

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6. Derivation

This section describes a general approach for measuring coastal submergence with the C-CAP data.

Some categories of change are more definitive than others. Although the regional feature focuses on the
conversion of undeveloped land to open water, the entire approach is presented to permit a more
thorough review of the methods and possible limitations of the data. For the purposes of this analysis,
the Mid-Atlantic region is defined as New York, New Jersey, Delaware, Maryland, and Virginia; the
Southeast includes North Carolina, South Carolina, Georgia, and the Atlantic coast of Florida (including
all of Monroe County).

Simplifying the Land Classification

The first step was to group the C-CAP land classes into four general classes relevant for measuring the
possible submergence of coastal land, as shown in Table TD-2: dry land, palustrine (largely nontidal,
freshwater) wetlands, tidal wetlands, and open water. The developed land categories are omitted for
two reasons:

1.	Developed lands are generally protected from shoreline erosion and rising sea level (Titus et al.,
2009), and thus rarely convert to tidal wetlands or open water.

2.	Although conversion of open water or tidal wetlands into developed land is rare (and strongly
discouraged by environmental regulations), the C-CAP data erroneously show it to have
occurred in many locations.4

Given the exclusion of developed lands, this regional feature should be construed as measuring
submergence of undeveloped lands.

Table TD-2. Reclassification for Evaluating Coastal Land Submergence

Land conversion category

C-CAP classification

Undeveloped Dry Land

6-12 and 20

Palustrine Wetlands

13, 14, and 15

Tidal Wetlands

16, 17, 18, 19

Open Water

21-23

Distinguishing Coastal Land Loss from Upland Changes

As a general rule, when all four general categories are present, dry land is inland and higher than
nontidal (palustrine) wetlands, which are higher than tidal wetlands, which are higher than open water.
Rising sea level tends to cause a higher category to convert to a lower category, and conversion from a
higher to lower category might indicate coastal submergence. Conversions from a lower to a higher

4 When the data show a new coastal development, sometimes pixels along the shore are shown as converting
from water to developed land when, in reality, the only change has been that the part of the pixel that was
originally undeveloped land has converted to developed land. New docks and boats sometimes show up as new
developed land. Pre-existing bridges sometimes show up as open water converting to developed land.

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category, by contrast, may indicate natural land accretion or fill activities, which generally require a
permit. In addition to actual conversions, the data may show conversions in either direction due to
"measurement error" resulting from the imperfections of interpreting remote sensing data.

This analysis focuses on the net conversion between categories rather than the total change in each
direction, because measurement error and shoreline processes unrelated to submergence have less
effect on net conversion than on the conversion in a particular direction. For example, a slight shift in
the grid that defines pixel boundaries can cause apparent land gain in some places and land loss in
others. Given the relative stability of most shores, these errors are more likely to cause the data to show
spurious changes—in both directions—than to hide actual changes. Inlet migration and other shoreline
processes may cause the shore to accrete in one place and erode nearby, and such shifts do not
represent coastal submergence.

Table TD-3 summarizes the relationship between coastal submergence and the types of coastal change
shown by the four land categories. Figure TD-1 illustrates two example environments. Both the table
and the figure distinguish three types of conversions: those that are included in the regional feature;
those that could generally be included in a land loss indicator, but are excluded from this edition of the
regional feature because additional review is needed; and conversions that might result from coastal
submergence, but are often caused by unrelated factors.

Conversion of land to tidal open water generally is an indicator of coastal submergence. Because remote
sensing is well-suited to distinguishing land from open water, the regional feature includes conversion of
land to open water, as shown in the final column of Table TD-3.

Table TD-3. Does Conversion Between Classes Generally Represent Coastal Submergence?

From>U

Dry land3

Dry land

Palustrineb

No

Tidal wetland0

Noe

Open water

If tidald

Palustrine wetland3

Noe

If tidald

Tidal wetland

Yes

Open water

a Changes involving developed lands, C-CAP categories 2-5, are excluded from the feature, but would

represent coastal land loss,
b "Palustrine" includes tidal freshwater wetlands.

c "Tidal wetland" includes both "estuarine wetlands" and "unconsolidated shore," but the C-CAP data set

does not distinguish tidal freshwater wetlands from nontidal palustrine wetlands,
d "If tidal" means that an additional data set is used to determine whether the open water is tidal or
nontidal.

e Net conversions from dry land and palustrine wetlands to tidal wetlands would generally represent net
coastal submergence, but additional review of the data is necessary to ascertain whether C-CAP provides
a representative measurement of such conversions.

* Treated as an offset to conversion in the other direction, when calculating net conversion.

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Figure TD-1. Land Conversions Included and Excluded in this Analysis

Conversions included in the report

Dry land tidal water
| Nontidal wetland -) tidal water
I Tidal wetlandtidal water

Conversions included in general approach,
but results not displayed in the report

| Developed land tidal wetland orwater
Nontidal wetland tidal wetiand
Dry land tidal wetland

Conversions that are not
necessarily coas tal s ubmergence

Dry land nontidal wetland
I Any land nontidal water

Checkerboard patterns signify co wersio ns i n th e o p posite
direction of sol id colors.

Both sketches show a barrier island that migrates inland and submergence from higher water levels along the
mainland shore, (a) On the ocean side, the undeveloped dry land converts to intertidal beach, and beach to open
water. The landward transport of sand, however, elevates land surfaces on the bay side, which converts some shallow
water to marsh and some marsh to dry land. On the mainland shore, dry land converts to tidal wetland, and tidal
wetland coverts to open water. The regional feature in the Indicators report includes the net conversions to open
water, but because additional review is required, it does not include conversions between dry land and tidal wetlands,
(b) The barrier island migrates as in (a), but the regional feature does not include conversions involving developed
lands. Farther inland, the rising bay leads to a higher water table, which in turn saturates some soils enough to
convert dry land to nontidal wetlands, and raises the level of the nearby freshwater lake. The higher lake also converts
previously dry land to nontidal wetlands, and nontidal wetlands to nontidal open water. Although the conversion in
this particular case might be attributed to rising sea level, in general, lake shorelines and the boundaries of nontidal
wetlands change for many reasons unrelated to rising sea level. Therefore, this analysis does not treat changes in
nontidal open water or conversions of dry land to nontidal wetlands as a form of coastal submergence.

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Conversion of dry land or palustrine wetlands to tidal wetlands is one of the more commonly discussed
consequences of sea level rise (e.g., Titus et al., 2009; Titus, 2011), and it would generally indicate
coastal submergence. Additional review is necessary, however, to ensure that the C-CAP data provide a
representative estimate of the net conversion of these relatively high lands to tidal wetlands.

Finally, this feature excludes net conversion of dry land to palustrine wetlands, because those
conversions do not necessarily indicate coastal submergence. Rising sea level can cause low-lying dry
land to convert to palustrine wetlands under a variety of circumstances. Yet most palustrine wetlands
are substantially above sea level, and conversions of dry land to palustrine wetlands at substantial
elevations are unrelated to coastal submergence. No multi-state data set is available to distinguish
conversions caused by submergence from those that are not.

Classifying Open Water Conversions as Tidal or Nontidal

If dry land converts to tidal open water (e.g., beach erosion or bluff erosion), then coastal land is lost.
Yet dry land might convert to nontidal open water if a pond is excavated for agricultural, stormwater, or
industrial purposes—or if the water level in a lake happens to be higher because it was a wet year.
C-CAP does not distinguish between tidal and nontidal open water, so it was necessary to use additional
data sets, discussed below.

Many wetlands data sets keep track of whether open water is tidal or nontidal. Unfortunately, they are
not revised with a regular five-year frequency, and many of them are relatively old. Thus, using them to
distinguish coastal land loss from upland land conversion might require considerable interpretation,
analogous to the effort that was necessary to distinguish tidal from nontidal wetlands in the C-CAP data
set.

An alternative approach, followed here, is to use available elevation data as a proxy for whether land
converts to or from tidal or nontidal open water. While the vintage of high-resolution elevation data
varies, it is generally more recent than 2006 and in some cases more recent than 2011. With the
exception of high bluffs in a few areas, if high-elevation land becomes open water, it is not coastal land
loss, and if land of any elevation becomes high-elevation water, it is virtually never coastal land loss.
Similarly, it is virtually never coastal land gain when water becomes land if either the land or the water
has a high elevation.

Conversely, nontidal open water is rare within 1 meter above mean high water (MHW), except for
artificially managed bodies of water such as Florida's water management canals. If newly created land
has an elevation within about 50 centimeters (cm) above spring high water, it is likely to be coastal land
accretion; and if land below 1 meter converts to open water, it is almost always tidal open water. The
same situation largely pertains when the elevation of the water surface is close to sea level, with one
caveat: Elevation of water bodies based solely on lidar sometimes provides an erroneously low reading,
so a different data source is necessary for elevation of water surfaces.

In light of these considerations, EPA's approach defines the coastal area vulnerable to inundation as
follows:

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•	Include land and water within 100 meters of the open coast—including large bays and sounds—
to account for shore erosion and accretion.5

•	Include land and water less than 3 feet above mean higher high water (MHHW), based primarily
on the NOAA sea level rise viewer data for land elevations, but also based on USGS 7.5-minute
quadrangles where lidar elevation data are unavailable (i.e., open water areas and certain
locations not yet covered by lidar). Exclude dry land, nontidal wetlands, and open water above
that elevation.

•	Include all tidal wetlands regardless of measured elevation.

•	Exclude conversions that are clearly the result of mining or construction projects, unless the
water elevations are below MHHW. Beach nourishment projects that reclaim land from the sea
are treated as land gain; excavations near the shore that create open water are treated as land
loss.

The 3-foot elevation cutoff was chosen to ensure that all lands within approximately 1 foot above the
tidal wetland boundary are included. In areas with a large tide range, high marsh generally extends up to
spring high water, which can be 1 to 2 feet above MHHW. In areas with negligible tides, high marsh can
extend 1 to 2 feet above MHHW as a result of wind generated tides. The 3-foot layer would thus include
all land that is within 1 to 2 feet above the tidal-wetland boundary.

To account for potential measurement error in the lidar data, the NOAA sea level rise viewer provides a
confidence layer, i.e., lidar-based data sets that identify land whose measured elevation is—with a high
degree of confidence—less than a given distance above MHHW. For example, the 3-foot layer (which
this analysis uses) includes all land whose elevation above MHHW is less than 3 feet plus the root mean
squared error of the elevation data. For further details, see Schmid et al. (undated).

NOAA's data layer does not include elevations for lakes and ponds, because lidar does not measure
elevations of water surfaces. (The data layer provides values for the purposes of the viewer, but those
values do not represent measured elevations.) Fortunately, other elevation data sources with less
accuracy, such as USGS topographic maps, avoid this problem. Thus, EPA used a second data set to
remove any locations shown to be above 10 feet in places where lidar does not provide an elevation,
such as inland lakes.6

Results: Land Cover Change Matrices

Tables TD-4 and TD-5 are region-specific change matrices, which quantify changes between the four
primary land cover categories for each of the three lustrums, along with the corresponding cumulative
net change. Each table provides the extent of change in square miles, which is found by dividing pixel
counts by 2,878 (the number of 30 x 30 meter pixels per square mile).

5	This version of the regional feature relies on visual inspection of the results to ensure that shoreline areas are
not excluded, which was feasible because bluff erosion is not a major factor in the Mid-Atlantic or Southeast.
This step could also be automated using a shoreline data file.

6	This version of the regional feature relies on visual inspection of inland lakes and USGS 7.5-minute quadrangles,
but it could also be automated using the USGS National Elevation Data Set.

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The final column in each table shows the net change of undeveloped land to open water compared with
the 1996 baseline, as shown in Figures 1 and 2 of this regional feature. For transparency, the tables
below include the other conversion categories.

Table TD-4. Results for the Mid-Atlantic Region

Change matrix: 1996 2001 (square miles)

Net change: 1996 2001 (square miles)

From\l/
To->

Upland

Palus-
trine

Tidal
wetland

Water

Upland

1,555.90

2.19

2.22

1.28

Palus-
trine

3.37

995.57

0.25

0.09

Tidal
wetland

0.95

0.28

1,148.9

0.91

Water

1.44

0.73

29.23

9,165.5













Change matrix: 2001 2006 (square miles)

From\l/
To->

Upland

Palus-
trine

Tidal
wetland

Water

Upland

1,562.63

0.26

0.34

3.03

Palus-
trine

10.72

999.42

0.05

2.07

Tidal
wetland

5.03

0.11

1,136.58

6.56

Water

3.53

0.50

23.22

9,162.81











Change matrix: 2006 2011 (square miles)

From\l/
To->

Upland

Palus-
trine

Tidal
wetland

Water

Upland

1,601.01

2.73

2.51

2.22

Palus-
trine

4.59

964.30

0.14

0.52

Tidal
wetland

0.56

0.03

1,132.68

1.43

Water

0.76

0.80

23.92

9,135.99











From\l/
To->

Upland

Palus-
trine

Tidal
wetland

Water

Upland

NA

-1.18

1.27

-0.16

Palus-
trine



NA

-0.02

-0.64

Tidal
wetland





NA

-0.76

Water







NA

Total
change

0.07

-0.51

2.00

-1.56

Net change: 1996 2006 (square miles)

From\l/
To->

Upland

Palus-
trine

Tidal
wetland

Water

Upland

NA

-11.64

-3.42

-0.66

Palus-
trine



NA

-0.08

0.92

Tidal
wetland





NA

4.80

Water







NA

Total
change

15.71

-12.48

-8.30

5.07



Net change: 1996 2011 (square miles)

From\l/
To->

Upland

Palus-
trine

Tidal
wetland

Water

Upland

NA

-13.49

-1.46

0.80

Palus-
trine



NA

0.03

0.65

Tidal
wetland





NA

2.10

Water







NA

Total
change

14.16

-14.17

-3.54

3.55

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Table TD-5. Results for the Southeast Region

Change matrix: 1996 2001 (square miles)

From\l/
To->

Upland

Palus-
trine

Tidal
wetland

Water

Upland

3,178.58

30.65

3.48

4.97

Palus-
trine

37.30

4,044.46

2.37

3.24

Tidal
wetland

3.97

1.74

2,222.16

8.44

Water

3.07

2.13

155.28

11,485.13













Change matrix: 2001 2006 (square miles)

From\l/
To->

Upland

Palus-
trine

Tidal
wetland

Water

Upland

3,235.55

0.38

0.71

3.89

Palus-
trine

16.12

4,115.13

0.02

1.35

Tidal
wetland

3.08

0.21

2,243.94

4.02

Water

1.94

0.70

150.37

11,568.98













Change matrix: 2006 2011 (square miles)

From\l/
To->

Upland

Palus-
trine

Tidal
wetland

Water

Upland

3,258.45

1.52

1.75

2.92

Palus-
trine

12.10

4,101.05

0.03

3.24

Tidal
wetland

3.60

0.10

2,228.67

2.94

Water

1.98

1.97

150.25

11,570.33











Net change: 1996 2001 (square miles)

From\l/
To->

Upland

Palus-
trine

Tidal
wetland

Water

Upland

NA

-6.65

-0.49

1.91

Palus-
trine



NA

0.63

1.12

Tidal
wetland





NA

5.35

Water







NA

Total
change

5.23

-8.40

-5.21

8.38



Net change: 1996 2006 (square miles)

From\l/
To->

Upland

Palus-
trine

Tidal
wetland

Water

Upland

NA

-22.39

-2.86

3.87

Palus-
trine



NA

0.44

1.76

Tidal
wetland





NA

7.40

Water







NA

Total
change

21.39

-24.59

-9.83

13.03

Net change: 1996 2011 (square miles)

From\l/
To->

Upland

Palus-
trine

Tidal
wetland

Water

Upland

NA

-32.97

-4.71

4.81

Palus-
trine



NA

0.38

3.03

Tidal
wetland





NA

8.60

Water







NA

Total
change

32.87

-36.38

-12.93

16.43

7. Quality Assurance and Quality Control

Thorough documentation of the quality assurance and quality control (QA/QC) methods and results is
available in the technical references for the NLCD and C-CAP. Publications are available at:
https://coast.noaa.gov/dataregistrv/search/collection. Accuracy assessments have been conducted for
the NLCD (Wickham et al., 2010, 2013) and for C-CAP (e.g., Washington Department of Ecology, 2013;
NOAA, 2013).

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Analysis

8.	Comparability Over Time and Space

The same general data collection and analytical techniques have been applied for all of the time periods
covered by this regional feature. Nevertheless, the methods are not precisely the same for all periods of
time, because the C-CAP data for the year 2001 are based on remote sensing from that year, while the
C-CAP data for other years are based on a combination of the remote sensing from 2001 and change
analysis using 2001 as a base year.

C-CAP employs the same procedures for all locations, except for those differences that inherently result
from differences in land cover. The use of ancillary wetlands data, for example, is greater in areas with
the greatest amount of wetlands.

9.	Data Limitations

Factors that may affect the confidence, application, or conclusions drawn from this regional feature
generally fall into two categories: limitations in scope and limitations of accuracy.

1.	The scope of this feature does not perfectly match the submergence of coastal land caused by
changing climate. By design, the feature is under-inclusive because it omits the following types
of coastal submergence:

•	Conversion of developed land to water

•	Conversion of dry land to tidal wetland

•	Conversion of dry land to nontidal wetlands resulting from higher water levels
The feature is also over-inclusive, in that:

•	Only a portion of relative sea level rise is caused by climate change, so only a portion of
land conversions from sea level rise are attributable to climate change.

•	Land can convert to tidal open water for reasons unrelated to relative sea level rise,
including wave-induced erosion, invasive species or changes in hydrology that kill marsh
vegetation, and construction of canals. Also, shore protection and infrastructure projects
can convert water to dry land.

2.	The accuracy of this feature has not been assessed, and there are reasons to expect significant
error. See Section 10 for additional discussion of accuracy and possible sources of uncertainty.

10.	Sources of Uncertainty

This regional feature is based on the sum of many pixels, relying on the assumption that the land or
water class assigned to a given pixel applies to the entire pixel. Along the shore, however, pixels are part
land and part water. Thus, the feature's accuracy is limited by both the accuracy and interpretation of

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individual pixels (map accuracy), and by the extent to which errors at the pixel level tend to accumulate
or offset one another (bias).

Map Accuracy: Interpretation of Individual Pixels

Accuracy Assessments

Accuracy of C-CAP pixels is limited by the factors present in all land cover data sets. Accuracy
assessments of the NLCD (Wickham et al., 2010, 2013) suggest that individual pixels are mapped with
approximately 79 percent accuracy for all of the NLCD (Anderson Level 2) categories, and 84 percent
accuracy when aggregated to the Level 1 categories (Wickham et al., 2013). These assessments do not
differentiate coastal from inland areas—and they may have excluded some shorelines.7

Accuracy assessments of C-CAP in Washington state and the western Great Lakes found similar overall
accuracy. When categories are aggregated to dry land, wetland, and open water—as this feature does—
the accuracy was 95 percent and 96 percent, respectively (Washington Department of Ecology, 2013;
NOAA, 2013).

The most recent accuracy assessment of the NLCD has also evaluated the accuracy with which the data
capture changes in land cover between 2006 and 2011. Wickham et al. (2013) found that the overall
accuracy of whether land cover changed was approximately 95 percent—higher than the accuracy of
individual pixels, although that higher accuracy is largely driven by the fact that an overwhelming
majority of pixels do not change and that fact is correctly captured by the data. Within the sample, the
NLCD and the high-resolution information agreed that there was no change for 97.24 percent of the
cells, and that there was a change for 1.43 percent of the cells. For 1.04 percent of the cells, however,
the NLCD failed to notice actual change, while for 0.263 percent, the NLCD incorrectly found that change
had occurred. Thus, 84.5 percent of the change detected by NLCD actually occurred (user accuracy), but
the NLCD only picked up 57.4 percent of the actual change (producer accuracy). The higher-resolution
data showed that 2.5 percent of the pixels changed, while the NLCD only shows 1.7 percent of the cells
as having changed. Stehman and Wickham (2006) show, however, that this type of analysis cannot
necessarily provide a statistically valid estimate of the accuracy of estimates of net change, and that the
necessary accuracy assessment for all of the NLCD classes of change would be cost-prohibitive.

Land loss or land gain detected by NLCD appears to be more accurate than estimated shifts from one
class of land to another. Wickham et al. (2013) found accuracies of 76 percent, 80 percent, and 93
percent when the NLCD detected land loss, land accretion, or open water remaining as water,
respectively (user accuracy). NLCD is considerably less successful at detecting actual land loss and land
gain (producer accuracy): when a high resolution data source detected land loss, land accretion, or
water remaining as water, C-CAP matched the high-resolution data for only 21 percent, 39 percent, and
86 percent of the cells, respectively (Wickham et al. 2013, p. 301).

The accuracy assessments of the C-CAP change analyses did not collect sufficient data to make class-
specific estimates of accuracy. Unlike the assessments of the NLCD, the C-CAP accuracy assessments

7 To ensure that the accuracy assessment results for open water were not unduly affected by large bodies of
water, large bodies of water such as Pamlico Sound, Chesapeake Bay, and the oceans were deliberately
excluded. Imprecision in the shoreline files used to exclude large bodies of water may have also excluded the
shore itself.

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generally show that C-CAP detects more change than higher-resolution data. For example, the
Washington state assessment found a user accuracy of 45 to 50 percent and a producer accuracy of 63
to 80 percent for the case where land cover changes (Washington Department of Ecology, 2013, pp. 6-
8). That study did not measure the accuracy associated with conversions between land and water.

Possible Sources of Mapping Error

No comprehensive catalogue of mapping error is available for C-CAP. The following three sources are
potentially significant:

•	Tidal variations. From lustrum to lustrum, the remote sensing imagery may be based on
different positions of the tides. NOAA attempts to ensure that all data are based on a consistent
position of the tides, but some variation is inevitable because the time of the tides varies. With
approximately 22 observations per year and a low tide every 12% hours, only two images per
year would be taken during the hour of low tide.8 (See discussion of remote sensing in Section
5.) Those two images may both be obscured by clouds or leaves in some locations, requiring the
use of images more than 30 minutes before or after high low. Even if neither clouds nor trees
obscure the image, the elevation of low tide varies greatly over the course of the year. The
spring tide range (full and new moons) is often about 50 percent greater than the neap-tide
range (quarter moons), and the two low tides on a given day also have different heights. Winds
can also cause water levels to diverge from what would be expected based solely on the
astronomic tides. Thus, even in an area where the shoreline does not change, C-CAP might show
land loss for a given time period if the first image is taken at a relatively low tide while the
second image was taken at a relatively high tide. This is especially the case along mudflats and
beaches, where wet soils rather than vegetation lines control the zonation.

•	Conversion to tidal open water from excavation of ponds or lake-level changes. Although
remote sensing can detect the difference between land cover and open water, it cannot detect
whether the open water is tidal. Instead, this regional feature relies on classifying open water
based on elevation. This approach has several limitations:

•	High resolution elevation data are lacking for South Carolina and part of Florida.

•	High-resolution elevation data often mischaracterize water elevations, requiring visual
inspection and/or reliance on secondary elevation data sources.

•	Nontidal open water exists at very low elevations in very flat areas.9

•	Conversion of land to coastal development. C-CAP might erroneously show some cells along
the shore as converting from water to land as a result of coastal development. A cell that is 50
percent water and 50 percent undeveloped land, for example, might be classified as water. If
such a cell is developed as part of a larger development, the cell might be reclassified as

8	That is, the time of day is within the hour of high tide about 8 percent of the time, and 8 percent of 22 images
per year is 1.7.

9	Including conversion of land to nontidal open water in very low-lying areas would not always be an error. For
example, ponds may expand because sea level rise causes water tables to rise; or ponds are created by the
mining of sand used to elevate the grade and thereby prevent inundation of other lands.

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developed land. Thus, the cell might be classified as a change from water to developed land
instead of a change from undeveloped to developed land.

Accuracy of this Regional Feature

Published accuracy assessments generally focus on the accuracy of individual pixels, not on the accuracy
of the resulting estimates of proportions or sums. These assessments show that land cover data
contribute a substantial amount of information and are often more useful than the available
alternatives. Yet mixed pixels and systematic error can impair the reliability of an indicator based on the
sum of many pixels, even when they are drawn from a reasonably accurate map. The focus of existing
accuracy assessments on individual pixels does not address whether or not limitations in the data
undermine the usefulness of the data for creating an indicator.

Methods have been developed and applied for assessing estimates of net change (Stehman and
Wickham, 2006), but they have not been applied to C-CAP results. An accuracy assessment of this
regional feature is necessary before confidence in it can be high. Comparison with an independent data
set such as that used for the NWI Status and Trends reports (e.g. Dahl, 2006; Dahl, 2011; Dahl and
Stedman, 2013) would be appropriate.

Mixed Pixels

Like most quantifications of land cover, this analysis makes the fundamental oversimplification that land
cover is uniform within each cell. Challenges related to this "mixed pixel" problem (Fisher, 1997) can be
safely disregarded if areas with homogenous land cover are large relative to the cell size. Conversely, in
constructing an indicator of shoreline migration, the implications of mixed pixels must be part of the
analysis because the shoreline consists of mixed pixels. The fact that shorelines generally change very
little compared with the size of a pixel affects both accuracy at the pixel level and the accuracy of an
indicator or feature based on the sum of pixel-level changes.

Over the course of five or even 15 years, most shorelines change by a small fraction of the 30-meter
pixel width. Thus, a land-loss indicator based on the sum of many 30-meter pixels will only be useful if
the pixels where the change is too small to be detected (and thus assumed to be zero) are roughly offset
by pixels where the change is detected (and thus assumed to be 900 m2). The error introduced by
assuming that the entire mixed pixel is either water or land is a type of "scale error;" that is, the error
becomes less, and eventually negligible, as pixel size decreases.10

Figure TD-2 illustrates the general case of small shoreline change relative to pixel size. The figure
assumes that pixels with a majority of water are classified as water. While that threshold is usually
higher,11 the same concepts apply regardless of the threshold. Initially, seven of the 15 pixels along the

10	Scale error is the rounding error necessitated by classifying a mixed pixel as one category or the other. One
might define classification error as follows: e, = X-, - C\, where X is the true area of water and C is either 0 or 900
m2. If there is no measurement error (i.e., \etJ<450 m2 so that measurement error has no impact on Q), then all
error is scale error.

11	In general, a pixel is classified as "water" if the spectral signature is more consistent with water than with land.
The threshold for classifying a pixel as water varies with locations. The NLCD has consistently defined open
water as areas with open water, "generally with less than 25% cover of vegetation or soil." See MRLC (undated)
and Wickham et al. (2013), p. 295.

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shore are more than 50 percent water, and the shoreline is about the length of 12 pixels. During a given
time period, the shore retreats by about 1/6 of the width of a pixel, so the total land loss is about 2
pixels. Two pixels that had been entirely dry land become partly open water, and one pixel loses the
small amount of land it originally had. At the end of the time period, the majority of the pixels labeled
"2" and "3" are water; pixel "1" is approximately 50 percent water as well. With the assumed
classification procedure, two or three pixels convert from land to water, which reasonably reflects the
actual land loss of two pixels. The other 14 pixels where the land loss is undetected and rounded to zero
are offset by these two or three pixels where land loss is detected and assumed to be the entire pixel.

Figure TD-2. Illustration of the "Mixed Pixel" Problem



Boy









J

























i



Land



















































































This figure shows the impact of the "mixed pixel" problem when shoreline retreats a small fraction of the
width of a pixel. In this conceptual map, dark blue represents open water and white represents land. Light
blue shows the dry land portion of pixels classified as water at the beginning of the time period. Cells 1, 2,
and 3 might be classified as open water after the shore erodes.

Scale error does not necessarily compromise the validity of an indicator based on the sum of all pixels.
The grid that defines the pixel boundaries is set independently of the shoreline, so the pixel-specific
scale error is random with a mean of zero.12 Thus, while the scale error can be large at the scale of a

12 The scale error for the mixed pixels would have a rectangular distribution from -450 m2 to +450 m2. Given the
well-established moments of a rectangular distribution, the mean scale error is zero and a§ = 67,500 m4; i.e.,
-------
pixel, it should be very small for a shoreline 100 kilometers long.13 Random measurement errors also
tend to cancel and make a negligible contribution to a total.

Systematic Error

Measurement error is not always random. Systematic measurement errors tend to accumulate rather
than cancel out as one calculates the total (e.g., see Cochran, 1977). Nevertheless, a systematic error
concerning the area of water in a sum of mixed pixels does not necessarily provide a poor estimate of
the change in the area of water (i.e., land loss). For example, if it were shown that C-CAP classifies cells
with at least H percent water as being water, and H varies but is on the order of 20 or 30 percent, then
C-CAP would overestimate the area of water among the mixed pixels in possibly unpredictable ways. Yet
the estimated change could still be reasonably accurate,14 as long as the procedure overestimates the
area of water consistently.

The consistency of C-CAP's measurement error from period to period is not known. The procedures
used to classify land cover during the base year differ from the procedures used during subsequent
years, so it is possible that the measurement error is not consistent from year to year. Significant
classification errors are possible: The tendency for the change analysis to discount small changes could
mean that an indicator based on a sum of pixels does not fully reflect the land loss or gain caused by

13	If scale error is uncorrelated across pixels and measurement error is negligible, the variance of the sum of pixels
would be cr| =£f aj =N 67,500 m4. If the shoreline is 100 km, N = 3,333 so cr| « 225,000,000 m4 and

as =0.015 km2. As Figure B shows, the scale error between adjacent cells is correlated, but that correlation
becomes negligible more than five to 10 cells out. Conservatively assuming perfect correlation between the 10
adjacent cells, the standard deviation would be a factor of 10 greater, which is still negligible for a shoreline of
100 km or longer.

14	For example, suppose that the probability that a pixel will be classified is an unknown function of X,:

prat>(class=water) = prob(C,=l) = F(X,), with F(0)=0 and F(l)=l.

In this note, all areas are expressed in pixels rather than m2. Among the mixed pixels, X, is uniformly distributed
between 0 and 1, so the expected value of the sum of pixels Si would be:

E(Si) = Nw+ Nm JgF(y)dy,

where Nw and Nm are the number of all-water and mixed pixels, respectively. In the ideal case with no
measurement error where F is a step function

F{X) = 0 for X < 0.5 and F(X) = 1 for X > 0.5, E(Si) = Nw + Nm /2.

Suppose shores erode by a consistent amount and convert an area of land equal to Nm z pixels to open water,
where z is a small fraction (e.g., shores erode by approximately 30z meters, a small fraction z of the pixel
dimension). The amount of water increases in every pixel by z, except for those pixels for which 1-X,
-------
small changes.15 Moreover, classification errors may be biased or highly correlated across cells, but in
different ways for different years. Along beaches and mudflats, the classifications of land and water are
sensitive to whether water levels in estuaries were atypically low or high when the imagery was taken.
Errors may be correlated across pixels because a single Landsat pass may obtain imagery for a large
section of coast; if estuarine water levels are high or low due to rainfall, such conditions may persist and
apply elsewhere. Interpretation errors may also be systematic to the extent that they result from the
consistent application of an imperfect procedure.

11.	Sources of Variability

As with the other time series indicators and features in this report, estimates of change from period to
period have far more uncertainty than estimates over the entire period. Coastal erosion in a given
region may be episodic, resulting from storms or an unusually high rate of sea level rise over a given
five-year period. Rates of sea level rise may also be greater during one time period than during the next.
The geography of the U.S. coast is highly variable, and there is no reason to expect land loss or gain at
one location to be similar to land loss or gain elsewhere.

12.	Statistical/Trend Analysis

The data in this feature have not been analyzed to determine whether they reflect statistically
significant changes over time.

References

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system for use with remote sensor data. Geological Survey Professional Paper 964. U.S. Geological
Survey, http://landcover.usgs.gov/pdf/anderson.pdf

Cochran, W.G. 1977. Sampling Techniques. New York. Wiley and Sons.

Cowardin, L.M., V. Carter, F.C. Golet, and E.T. LaRoe. 1979. Classification of wetlands and deepwater
habitats of the United States. U.S. Fish and Wildlife Service.

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Fisher, P. 1997. The pixel: A snare and a delusion. Int. J. Remote Sens. 18:679-685.

15 The key assumption in the previous footnote is that the same, possibly flawed, F(X) classification applies for
both periods of time. If different procedures are applied in different years, then our demonstration that the
indicator should be unbiased no longer applies.

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Fry, J.A., G. Xian, S. Jin, J.A. Dewitz, C.G. Homer, L. Yang, C.A. Barnes, N.D. Herold, and J. Wickham. 2011.
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