Finding pollution with aerial
infrared thermography
Under good conditions,
aerial infrared thermographers can scan up to hundreds of stream-miles in one
night, and produce a complete, accurate report in a timely manner.
by Gregory R. Stockton
The Industrial Physicist
– TIP Article 2004
http://www.aip.org/tip/INPHFA/vol-10/iss-2/p24.html
The Environmental
Protection Agency (EPA) has identified contaminated surface and drinking water
as one of the more serious environmental problems facing the United States.
Leaking sewage-collection lines, storm-water drain discharges, and illegal
connections to storm-water drainage systems can be identified by their thermal
infrared (IR) signatures during certain times of the year. As these sources of
pollution leak, seep, or empty into creeks, streams, rivers, and lakes, their
thermal signatures vary from their surroundings, and aerial IR thermography can
accurately pinpoint them.
Typically, liquids flowing
into a stream or lake appear warmer than the surface of the larger body of
water, particularly during cooler times of the year, because of the relative
warmth of the ground a short distance below the surface (Figure 1a). Leaks from
nearby lines often come to the surface through lateral flows to a stream or
lake bed, or to a slope (Figure 1b) leading down to the surface of the water.
These leak areas and the warm plume of liquid joining or flowing downstream
with the cooler water are visible in the thermal IR spectrum. In most parts of
the United States, late fall, winter, and early spring are well suited to this
type of inspection because of the greater difference in temperature between
ground and surface water, as well as the minimal interference from overhanging
foliage (Figure 1c).
Why the need?
The EPA enforces
compliance with the federal Water Pollution Control Act and the Clean Water
Act. Under these laws and other requirements, municipalities must develop,
implement, and enforce a stormwater management program designed to minimize the
amount of pollutants discharged into local surface waters.
Figure 1. Aerial infrared
images show liquid outfall as a brighter (warmer) plume on December 1, 2000
(left), on a bank slope (middle), and with reduced foliage on March 13, 2003
(right)
Aerial IR thermographic
surveys can help municipalities fulfill this obligation. Stormwater collection
systems are engineered to efficiently drain selected areas and to discharge the
runoff into surface waters. All too often, these systems convey pollutants from
illicit connections, degraded sanitary sewers and septic tanks, and other
sources. Until now, locating these point sources has been a labor-intensive
task that often relied on taking samples blocks or miles from the actual
pollution source.
Traditional methods of
pollution-source detection, including on-the-ground water quality sampling and
visual stream surveys, do not provide effective coverage of large surface
waters, where many problems go undetected. Municipalities have become
interested in using alternate, cost-effective means of pollution detection that
overcome the limitations of the traditional laborintensive approaches. They
would like to identify and abate in-stream increases of bacteria, metals,
nutrients, pathogens, and herbicides; other pollutants from urbanization;
malfunctioning septic systems; illegal sanitary-sewer and storm-drain
connections; and other illicit discharges.
An aerial IR survey
provides an efficient and cost-effective way to find these point sources. After
ground verification and analysis of the information collected during an aerial
IR survey, officials can take action to deal with malfunctioning systems and
illicit discharges. Municipalities can also identify areas that contain
priority clusters or higher concentrations of pollutants and prepare lists of
individual property addresses located within these clusters. This type of
project demonstrates to local residents a heightened awareness by public
officials of illegal stream connections, septic-system failures, and general
water-quality issues, another requirement of the federal program.
Aerial IR surveys, ground
verification, and remedial follow-up provide measurable environmental results,
including enhanced in-stream water quality; recovery of aquatic species; and
improved collection systems, septic-system maintenance, and animal waste
management; as well as increased knowledge of groundwater movements.
Ground vs. aerial
Conducting a ground-based
visual survey of a stream requires walking the entire length on both sides
(Figure 2). A ground-based IR survey offers few advantages over a visual survey
and may cost more. Its major advantage is that inspectors need only test the
water outfalls that show heat signatures, which potentially increases the speed
of the survey if there are few anomalies. However, there are additional costs
involved with a ground-based IR survey. Given the expense of the personnel and
equipment needed, and assuming downtime for adverse weather, sick days, and/or
injuries, either type of ground-based survey costs more than most
municipalities can or will pay. In contrast, aerial IR surveying is quick and
efficient. Under good conditions, aerial IR thermographers can scan up to
hundreds of streammiles in one night, and produce a complete, accurate report
in a timely manner.
IR imagery often consists
of gray-scale pictures whose varying shades represent differences in
temperature and the emissivity of objects in the images. As a general rule, lighter
colors designate warmer objects and darker colors indicate cooler ones. All
objects in the images are detected at thermal IR wavelengths in the
3,000–5,000-nm (shortwave) or 8,000–14,000-nm (longwave) range.
Lights and other relatively hot objects are evident because of their heat
emissions.
Images taken with an IR
camera during a flight are often recorded on videotape and/or saved digitally
to on-board hardware and later converted to a digital image file, which can
then be modified in several ways to enhance its value to the end user.
Videotape records the highest-resolution IR images, although printed
thermographs and map data may serve as convenient references when accompanying
a report.
Figure 2.
A typical creek landscape, seen in early summer, illustrates the difficulty of
ground-based surveys, which require walking the entire length on both sides.
Equipment
Professional survey
results require equipment specifically designed for the task. In applications
that need a straight-down view or a large-area view, and/or where long
distances must be covered in a limited time, aerial IR thermography is superior
to ground-based IR in image quality and use. The selection of the proper
aircraft, camera mount, IR imager, navigational aids, recording medium,
workstation computer equipment, and pilot and crew is critical to success.
Both helicopters and light
airplanes can perform aerial IR surveys. Spatial resolution and thermal
sensitivity are all-important in aerial IR thermography. It is always better to
use a large pixel array, although larger lenses help if the customer will
accept some signal strength degradation. Using a more powerful lens does
improve clarity by reducing the ground resolution element (GRE)—the size
of one pixel on the ground for a given distance. This reduced GRE, however,
also reduces the sensor’s field of view, which limits the total area
covered on the ground. Moreover, an aircraft’s movements and vibrations,
particularly those of a helicopter, may cause image blurring or smearing, which
results from an increase in the apparent speed of the sensor’s view
across the ground. The GRE and other thermal-imager characteristics need to be
known before the aircraft and imager are selected for a particular job. Our
research and experience in aerial IR applications have shown, for example, that
a handheld, small-format imager held out the open window of a helicopter will
not produce professional results.
Well-maintained aircraft
and IR, video recording, and mapping equipment are essential to success.
Everything in the aircraft must be secured, and wires clearly labeled for quick
identification, placed out of the way, and shielded from electromagnetic
interference. Precise navigation is important in any aircraft but particularly
in nighttime aerial IR operations. To produce the most valuable report
possible, one must record the imagery and exact location of all areas surveyed.
Because the pilot and thermographer are extremely busy during the flight, one
or both might miss an anomaly. Thus, all imagery and matching Global
Positioning System (GPS) information need to be recorded. During postflight
analysis, each frame of the video will receive methodical and detailed
scrutiny. For this reason, the thermal-imager video output must be routed
through a device that encodes the video with a continuous stream of GPS
information. A digital videocassette recorder (VCR) tapes the annotated video
imagery, while a laptop computer with specialized mobile mapping software is
used to guide the aircraft and map the designated flight path.
Aerial IR imaging is not a
job for IR equipment operators or pilots who have not received specialized
training in such operations. The aircraft must fly over and along the
surface-drainage system in a manner that allows the imaging and recording on
digital videotape of the target creek, stream, river, or lake. In the cockpit,
moving-map software with GPS antennas similar to that used in some automobiles
permits the crew to monitor the flight path and the aircraft’s location
with respect to the drainage area, and guides the pilot along specific flight
lines to ensure complete coverage. The IR operator usually interrupts the
recording during turns outside the study area, which omits extraneous imagery.
Analysis
After the flight, the
videotaped imagery is analyzed using a digital VCR, a high-resolution TV
monitor, and an integrated computer system with video-capture hardware and
software. As the tape plays, the GPS-coded signal received and recorded during
the flight is decoded by a device called a video encoder/decoder, which
re-creates the original GPS signal and sends it to the computer so that its
mobile mapping software interprets the recorded signal as a live one. The
mapping software shows the position of the moving airplane superimposed on a
street map on the computer screen, while the recorded IR imagery of the area
below the airplane appears on a second monitor. GPS signals update the
airplane’s position once every second throughout the flight and at the
same rate during the post-flight analysis.
To find potential sources
of pollution, users view the tape in its entirety—pausing and playing it
backward and forward at regular speed and in slow motion as necessary. Each
hour of tape requires many hours of analysis to complete a report. After all
anomalous sources are found, they are marked on the topographic map, and IR
thermographs are digitally captured on videotape using specially designed
hardware and software. The captured image displays the annotation
data—such as date, time, latitude, and longitude—as a strip at the
bottom of the image. Each anomaly is assigned a number that corresponds to a
number on a specific image. The maps and digital images are then brought into
an image-processing software application and adjusted for such qualities as
contrast brightness before being scaled for final editing.
A
project’s results
In February 2002, the
Mecklenburg County Water Quality Program in North Carolina conducted a study to
test alternate methods of pollution-source detection. It sought to determine
the effectiveness of using aerial IR surveying along 27 miles of Little Sugar
and Briar Creeks. The survey pinpointed 62 heat anomalies along the two
streams. Field investigations of the anomalies revealed the following results:
- One anomaly was identified as a failing 15-in.
sewer line. Charlotte Mecklenburg Utilities replaced the line, and the
discharge stopped.
- Another anomaly was an illegal discharge into
the storm-drain system from a convenience store. The discharge was removed
from the storm drain and tied to the sanitary sewer system.
- Ten anomalies were identified as dry weather
flows to storm drains—that is, flowing water unrelated to
precipitation — with elevated fecal coliform bacteria levels.
Additional follow-up field investigations were conducted to identify the
sources of these problems.
- Twelve anomalies were no longer found to be
flowing during several field investigations. Inspectors carried out
additional investigations to check for recurrence of the discharges.
- Ten anomalies could not be located on the
ground. Additional follow-up was performed in an effort to identify them
- Five anomalies proved to be sewer-collection
system features with no discharges to surface waters. No further follow-
up was required.
- Another twelve anomalies were identified as
being dry-weather flows to storm drains but with no negative water quality
impacts. No further follow-up was required on these.
- Eleven anomalies were attributed to groundwater
flow. No further follow-up was required.
Conclusions
Municipalities must comply
with federal clean-water laws, and each must develop, implement, and enforce a
storm-water management program that has been designed to minimize the amount of
pollutants discharged into local waters. By using specialized equipment and
techniques, aerial IR thermographers can locate pollution point sources so
officials can act to prevent con-taminants from entering our waterways. Aerial
IR surveys will continue to assist municipalities in making U.S. waters,
wetlands, and watersheds better suited for drinking water and recreation while
creating a more hospitable environment for aquatic life.
Biography
Gregory R. Stockton is president of Stockton Infrared Thermographic
Services, Inc., in Randleman, North Carolina. This article is based on a
paper that he presented at Infra-Mation 2003, held in Las Vegas, Nevada, Oct.
13–16, 2003.