Applying Distance
to Spot Ratio Values
to Infrared Imagers for
Accurate Temperature Measurement
Warren
C. Garber & R. James Seffrin
Infraspection Institute
425 Ellis Street
Burlington, NJ 08016
609-239-4788
As
the art and science of infrared thermography has matured,
infrared test equipment has evolved. Technological advances
during the past 15 years have enabled equipment manufacturers
to design infrared imagers capable of providing real time
non-contact temperature measurements. The evolution of modern
imaging radiometers has progressed to the point that most
commercially available infrared cameras are now capable of
providing non-contact temperature measurements.
When using a radiometer to measure object
temperatures, several important factors must be addressed.
Among these are target emittance, atmospheric attenuation,
spectral response of the imaging radiometer, and measurement
spot size. While spot size is not defined in currently published
standards, it is generally defined as the area from which
radiometric or temperature data are derived. For accurate
temperature measurement, the spot size of the radiometer must
be smaller than the target being measured. Should the spot
size be larger than the target, error will be introduced into
the measurement. The amount of error will be dependent upon
a number of factors, none of which can be corrected for by
any means including radiometric software.
While many non-imaging radiometers now employ
a laser sighting system to project relative spot size onto
the object being measured, no such sighting system exists
for imaging radiometers. As such, it is impossible for a thermographer
to visually gauge the spot size of the imager in use. In fact,
many thermographers mistakenly believe that imaging radiometers
are capable of producing accurate temperatures equal to the
pixel size of the imager. Although many modern infrared imagers
are capable of measuring temperature, infrared equipment manufacturers
generally do not provide information regarding spot size nor
how to calculate it. In contrast, non-imaging radiometers
have always expressed spot size as a distance to target ratio
such as 50:1. Applying this ratio, at 50" from a target,
the spot size would be 1". This methodology provides
a simple and quick means for calculating spot size at any
distance from the target.
To date, manufacturers of infrared imagers
continue to apply the "slit response function test"
to imaging radiometers. From this test, the only figure consistently
reported is the milliradian angle at 50% of the radiance received
by the imager; this is known as the instantaneous field of
view or "IFOV". The results of the slit response
function test enable a user to calculate minimum target size
or the distance at which there is a 50% probability of detection
of a target.
Applying the slit response function test
values poses several problems. Among them are:
1.Because the slit response function
test is a measure of the visual performance of an infrared
imager, it has no bearing on the temperature measurement accuracy
of an imaging radiometer.
2. Slit response values do not state the geometric configuration
or orientation of the target tested.
3. The slit response test values do not specify the orientation
of the detector during testing.
4. Since quantitative thermographers are interested in accurate
temperature readings, temperature measurements based upon
50% accuracy are of little or no value to them.
By following the Guideline for Measuring
Distance/Target Size Values for Quantitative Thermal Imaging
Cameras published by Infraspection Institute, the authors
were able to calculate spot size ratio values for several
modern imaging radiometers for varying percentages of accuracy.
Table 1 lists the calculated ratio values for 98% accuracy.
Table 1: Distance to Target
Ratio Values for Imaging Radiometers - 98% Accuracy
The information contained in Table 1 was
derived using the normal lens supplied with each imager. Using
telephoto or wide angle lenses on any imaging radiometer will
change ratio values proportionate to the magnification power
of the lens. For example, using a 2x telephoto lens will effectively
double the ratio values in Table 1; use of a 2x wide angle
lens will effectively halve the listed values in the same
table.
Several interesting observations were made
from the data obtained during testing.
1. Spot measurement size for the radiometers
tested varied considerably from the theoretical values obtained
by using published IFOV values.
2. In some cases, the visual IFOV was up to five times smaller
than measurement spot size calculated from Table 1 values.
3. Target shape influences spot measurement size.
4. Some imaging radiometers had lower values when the target
was horizontally oriented; others had lower values when vertically
oriented.
5. Most imagers performed worst on circular targets.
6. For some imaging radiometers, the on-screen crosshair did
not always define the center of the measurement area.
7. Using electronic 'zoom' did not change measurement spot
size.
8. The distance to spot ratios listed in Table 1 can be used
to calculate the maximum distance for accurate temperature
measurement. For greatest accuracy, one should be conservative
in applying these numbers.
9. Spot measurement size varies linearly as distance to the
target increases/decreases.
How To Use Distance
to Target Ratio Values
The
distance to spot ratios listed in Table 1 can be used to calculate
either the maximum distance or minimum target size at 98%
accuracy.
1.
To calculate the minimum
target size at a given distance:
a.Divide the distance from
the camera lens to the target by the listed value that
corresponds to the shape of your target
Distance ÷ Listed
Value = Minimum Target Size
Example: You want to measure
the temperature of a circular target 10' away with a Flir
PM 390:
10' or (120") ÷
212 = 0.566" circular spot size.
2.
To calculate the maximum
distance for a given target size:
a. Measure or estimate
the size of your target
b. Multiply the listed value
by the target size to obtain the maximum distance
Listed Value x Target
Size = Maximum Distance
Example: You are inspecting
a 1" circular target with a Mikron 7102. How close
should you be to measure the temperature?
181 x 1" = 181"
or 15.08'
Applying the figures in Table
1, thermographers can develop simple diagrams similar to those
commonly used for spot radiometers. An example of such a diagram
is provided in Figure 1.
Figure 1: Calculated Minimum
Target Size for Horizontally Oriented Target Using Flir Prism
SP
.
Why IFOV Values Are
Inaccurate for Calculating Spot Size
Since many thermographers have long used
IFOV values to calculate spot size, it is interesting to note
how greatly this method differs from our results. The formula
is as follows:
Using the published IFOV values for a FLIR
ThermaCAM PM 575 at 30' (360") from target, we calculate:
It is interesting to note that using IFOV
value does not consider target shape nor does it state a percentage
of accuracy. In fact, this value is derived with the radiometer
receiving only 50% radiance from the blackbody simulator!
IFOV values do not relate to spot size since they are a measurement
of individual pixel size. Most imaging radiometers require
more than one pixel for accurate temperature measurement.
Since detectors vary between manufacturers so will the number
and orientation of the pixels required for accurate temperature
measurement.
Using the calculated ratio values from
Table 1 for a FLIR ThermaCAM PM 575 at 30' (360"), we
calculate:
Vertical rectangle:
360" ÷ 175 = 2.057"
Horizontal rectangle:
360" ÷
379 = 0.949"
Circular:
360"
÷ 144 = 2.500"
It is important to note that the above spot
sizes vary considerably from that calculated by using the
IFOV value. As stated before, spot size must be smaller than
the target in order to accurately measure target temperatures.
Radiometric software cannot correct temperatures obtained
with an incorrect spot size.
Conclusion
Using IFOV values does not provide meaningful
data with respect to spot measurement size of an imaging radiometer.
The Infraspection Institute Guideline for Measuring
Distance/Target Size Values for Quantitative Thermal Imaging
Cameras can be used to calculate distance to spot
ratios for any imaging radiometer. This test can be set up
with a minimum of equipment and facilities and provides meaningful
data about an individual radiometers accuracy. Knowing a radiometer's
accuracy enables a thermographer to better understand his/her
limitations when measuring temperatures.
Thermographers who have traditionally
relied on IFOV values should consider using ratio values instead.
This is especially true for anyone performing remote infrared
inspections of small targets such as overhead power lines
or substation components. In these situations, thermographers
performing quantitative inspections should consider moving
closer to subject targets or using a telephoto lens.
References
1. Guideline for Measuring Distance/Target
Size Values for Quantitative Thermal Imaging Cameras, Infraspection
Institute, 425 Ellis Street, Burlington, NJ 08016
2. Level II Certified Infrared Thermographer
Reference Manual, Infraspection Institute, 425 Ellis Street,
Burlington, NJ 08016
3. Level II Infrared Thermography Training
Course Manual, Flir Systems Inc., 16 Esquire Road, North
Billerica, MA 01862
4. Calculating Spot Measurement
Size for Imaging Radiometers, Warren Garber and Michael
R. Sharlon, IR/INFO 2002 Proceedings, Infraspection Institute,
425 Ellis Street, Burlington, NJ 08016
